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1
Section 9-4 Two Means:
Matched Pairs
In this section we deal with dependent samples. In other words, there is some relationship between the two samples so that each value in one sample is paired (naturally matched or coupled) with a corresponding value in the other sample.
So the two samples can be treated as matched pairs of values.
2
Examples:
• Blood pressure of patients before they are given medicine and after they take it.
• Predicted temperature (by Weather Forecast) and the actual temperature.
• Heights of selected people in the morning and their heights by night time.
• Test scores of selected students in Calculus-I and their scores in Calculus-II.
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Example:
First sample: weights of 5 students in April
Second sample: their weights in September
These weights make 5 matched pairs
Third line: differences between April weights and September weights (net change in weight for each student, separately)
In our calculations we only use differences d, not the values in the two samples.
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n = number of pairs of data.
d = mean value of the differences d for the paired sample data (equal to the
mean of the x – y values)
Notation for Dependent Samplesd = individual difference between the two values of a matched pair
µd = mean value of the differences d for the population of paired data
sd = standard deviation of the differences d for the paired sample data
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Requirements
1. The sample data are dependent (make matched pairs).
2. Either or both of these conditions is satisfied: The number of pairs of sample data is large (n > 30) or the pairs of values have differences that are from a population that is approximately normal.
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Tests for Matched Pairs
H0: d =
H1: d
, H1: d < , H1:
d>
The goal is to see whether there is a difference.
two tails left tail right tail
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t = d – µdsd
n
degrees of freedom df = n – 1
Hypothesis Test Statistic for Matched Pairs:
Note: d
=0 according to H0
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P-values and
Critical Values
Use Table A-3 (t-distribution)
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Example:
Use a 0.05 significance level to test the claim that for the population of students, the mean change in weight from September to April is 0 kg
(so there is no change, on the average)
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Example:
Weight gained = April weight – Sept. weight
d denotes the mean of the “April – Sept.” differences in weight; the claim is d = 0 kg
Step 1: claim is d = 0
Step 2: If original claim is not true, we have d ≠ 0
Step 3: H0: d = 0 (original claim)H1: d ≠ 0
Step 4: significance level is = 0.05
Step 5: use the student t distribution
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Example:
Step 6: find values of d and sd
differences are: –1, –1, 4, –2, 1d = 0.2 and sd = 2.4now compute the test statistic
Table A-3: df = n – 1, area in two tails is 0.05, yields a critical value t = ±2.776
t d dsdn
0.2 0
2.4
5
0.186
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Example:
Step 7: Because the test statistic does not fall in the critical region, we fail to reject the null hypothesis.
13
Example:
We conclude that there is sufficient evidence to support the claim that for the population of students, the mean change in weight from September to April is equal to 0 kg.
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Example:
The P-value method:
Using technology, we can find the P-value of 0.8605. (Using Table A-3 with the test statistic of t = 0.186 and 4 degrees of freedom, we can determine that the P-value is greater than 0.20.) We again fail to reject the null hypothesis, because the P-value is greater than the significance level of = 0.05.
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Confidence Intervals for Matched Pairs
where E = t/2sdn
d – E < µd < d + E
Critical values of tα/2 : Use Table A-3 with
df = n – 1 degrees of freedom.
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Example:
Construct a 95% confidence interval estimate of d , which is the mean of the “April–September” weight differences of college students in their freshman year.
= 0.2, sd = 2.4, n = 5, ta/2 = 2.776
Find the margin of error, E
d
E t 2
sdn
2.7762.4
53.0
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Example:
Construct the confidence interval:
We have 95% confidence that the limits of ─2.8 kg and 3.2 kg contain the true value of the mean weight change from September to April.
d E d d E0.2 3.0 d 0.2 3.0
2.8 d 3.2
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• Enter 1st sample in list L1 and 2nd sample in L2
• Clear screen, type L1─L2→L3 (use STO key)• Press STAT and select TESTS• Scroll down to T-Test for hypotheses testing• or to TInterval for confidence intervals
• Select Input: Data (not Stats) and use list L3
• Then proceed as if you had just one sample…
Dependent samples by TI-83/84
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Section 9-5
Comparing Variation in Two Samples
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Requirements
1. The two populations are independent.
2. The two samples are random samples.
3. The two populations are each normally distributed.
The last requirement is strict.
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Important:
• The first sample must have a larger sample standard deviation s1 than the second sample, i.e. we must have
s1 ≥ s2
• If this is not so, i.e. if s1 < s2 , then we will need to switch the indices 1 and 2, i.e. we need to label the second sample (and population) as first, and the first as second.
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Notation for Hypothesis Tests with Two Variances or Standard Deviations
s1 = first (larger) sample st. deviation
n1 = size of the first sample
1 = st. deviation of the first population
s2 n2 2 are used for the second sample and population
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Tests for Two Variances
H0: 1 =
2
H1: 1
2 , H1:
1>
2
Note: H1: 1<
2 is not considered.
Note: no numerical values for 1 or
2 are
claimed in the hypotheses.
The goal is to compare the two population variances (or standard deviations)
two tails right tail
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Critical Values: Using Table A-5, we obtain critical F values that are determined by the following three values:
s1F = s2
2
2
Test Statistic for Hypothesis Tests with Two Variances
1. The significance level
2. Numerator degrees of freedom = n1 – 1
3. Denominator degrees of freedom = n2 – 1
Where s12 is the first (larger) of
the two sample variances
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• The F distribution is not symmetric.
• Values of the F distribution cannot be negative, i.e. F ≥ 0.
• The exact shape of the F distribution depends on the two different degrees of freedom (numerator df and denominator df)
Properties of the F Distribution
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Density curve of F distribution
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If the two populations do have equal
variances, then F = will be close to 1
because and are close in value. s1
2 s22
s12
s22
Use of the F Distribution
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If the two populations have radically different variances, then F will be a large number.
Remember: the larger sample variance is s1 , so F is either equal to 1 or greater than 1.
2
Use of the F Distribution
29
Consequently, a value of F near 1 will be evidence in favor of the conclusion that 1 = 2 .
2 2
But a large value of F will be evidence against the conclusion of equality of the population variances.
Conclusions from the F Distribution
30
Critical region is shaded red: there we reject H0: 1=2
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To find a critical F value corresponding to a 0.05 significance level, refer to Table A-5 and use the right-tail area of 0.025 or 0.05, depending on the type of test:
Finding Critical F Values
Two-tailed test: use 0.025 in right tail
Right-tailed test: use 0.05 in right tail
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Below are sample weights (in g) of quarters made before 1964 and weights of quarters made after 1964. When designing coin vending machines, we must consider the standard deviations of pre-1964 quarters and post-1964 quarters. Use a 0.05 significance level to test the claim that the weights of pre-1964 quarters and the weights of post-1964 quarters are from populations with the same standard deviation.
Example:
33
Example:
Step 1: claim of equal standard deviations is equivalent to claim of equal variances
12 2
2
Step 2: if the original claim is false, then
12 2
2
Step 3: H0 : 12 2
2
H1 : 12 2
2
original claim
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Step 4: significance level is 0.05Example:
Step 5: involves two population variances, use F distribution variances
2 212 22
0.087001.9729
0.016194
sF
s
Step 6: calculate the test statistic
For the critical values in this two-tailed test, refer to Table A-5 for the area of 0.025 in the right tail. The critical value is 1.8752.
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Example:
Step 7: The test statistic F = 1.9729 does fall within the critical region, so we reject the null hypothesis of equal variances. There is sufficient evidence to warrant rejection of the claim of equal standard deviations.
36
Example:
Left tail is not used and need not be shown !
37
There is sufficient evidence to warrant rejection of the claim that the two standard deviations are equal.
The variation among weights of quarters made after 1964 is significantly different from the variation among weights of quarters made before 1964.
Conclusion:
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• Press STAT and select TESTS• Scroll down to 2-SampFTest press ENTER• Select Input: Data or Stats. For Stats:
• Type in sx1: (1st sample st. deviation)
• n1: (1st sample size)
• sx2: (2nd sample st. deviation)
• n2: (2nd sample size)
choose H1: 1 ≠2 <2 >2
(two tails) (left tail) (right tail)
Tests about two variances by TI-83/84
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Tests about two variances (continued)
• Press on Calculate• Read the test statistic F=…• and the P-value p=…• Note: the calculator does not require the first
sample variance be larger than the second. It can handle both left-tailed and right-tailed tests.