Deck 16: One-Way Analysis of Variance

A) observations are random.
B) observations are independent.
C) subjects are related.
D) there are equal numbers of observations in each group.

A) the variance within each group
B) the variance of the means
C) the variance of the total sample
D) the difference between the means

A) the populations have no variance.
B) the samples have equal variances.
C) the populations have equal variances.
D) the variances are normally distributed.

A) the null hypothesis is false.
B) the null hypothesis is true.
C) the null hypothesis is confused.
D) the experiment will have very little power.

A) the larger the value of F .
B) the smaller the value of F .
C) the smaller the value of the correlation coefficient.
D) the harder it is to find a significant difference.

A) the variance of the individual observations.
B) the variance of the group totals.
C) the variance of the error scores.
D) the variance of the means.

A) the variances would all be the same.
B) the sample means would all be the same.
C) the population means would all be the same.
D) every subject would have the same score.

A) the degrees of freedom for the Between Groups term.
B) the degrees of freedom for the Within Groups term.
C) only the total number of degrees of freedom.
D) both a and b

A) greater processing leads to greater recall.
B) less processing leads to greater recall.
C) the recall means are different in the different groups.
D) none of the above

A) the populations are normally distributed.
B) the populations follow a rectangular distribution.
C) the populations all have completely different shapes.
D) There is no assumption about the shape of the population.

A) the variability of the group means.
B) the variability within the group means.
C) the variability calculated for the scores within each group separately.
D) the variability within all of the data points.

A) random sampling.
B) random assignment.
C) equal sample sizes.
D) a significant F .

A) deals with multiple groups.
B) compares group variances.
C) makes different assumptions about the populations from which we sample.
D) none of the above

A) the total variance with the variance within groups.
B) the total variance with the variance between group means.
C) the variance between group means with the variance within groups.
D) the variance within groups with the variance among all data points.

A) differences between subjects in the same group.
B) differences between subjects in different groups.
C) the overall variability of scores in the experiment.
D) the misrecording of data.

A) the three population means are all different.
B) at least one of the population means is different from the others.
C) the three population means are equal to each other.
D) We can't tell from what is given here.

A) the average of the between group variances.
B) the average of the between group sums of squares.
C) the sum of squares of the within group variances.
D) the average of the within group variances.

A) approximately 0.
B) somewhere around 1.
C) at least 10.
D) the value of F is not dependent on the status of the null hypothesis.

A) all of the means are the same.
B) all of the means are different.
C) at least one of the means is different from at least one other mean.
D) only one mean is different from one other mean.

A) .05.
B) .05/6.
C) .30.
D) .01.

A) η² tends to overestimate the true value in the population.
B) ω² tends to overestimate the true value in the population.
C) calculation of η² uses the number of groups.
D) the calculation of ω² is quicker and easier.

A) the data are reasonably normal.
B) the variances are not too different.
C) the unequal variances are not paired with very unequal n s.
D) all of the above

A) η² = ω²
B) η² > ω²
C) η² ω ²
D) none of the above

A) be positive.
B) equal 1.0.
C) exceed the tabled value.
D) be less than the tabled value.

A) operating at a reduced level of α.
B) operating at an increased level of α.
C) not allowing you to make any comparisons unless the F is significant.
D) changing the error term.

A) 110.
B) 20.
C) 4.5.
D) 92.

A) the first one
B) the second one
C) both the first and second
D) Neither of these is a null hypothesis.

A) 1
B) 2
C) 3
D) 4

A) not allowing them.
B) doing nothing different.
C) averaging the means.
D) multiplying each squared deviation by n _j as we go along.

A) you have only two means.
B) you have two or three means.
C) you have many means.
D) you have a nonsignificant overall F .

A) SS _between
B) SS _within
C) SS _total
D) MS _error

A) means.
B) variances.
C) standard deviations.
D) F s.

A) a major problem.
B) a minor inconvenience.
C) something to be avoided at all costs.
D) impossible.

A) dividing the sums of squares by the degrees of freedom.
B) multiplying the degrees of freedom times the sums of squares.
C) dividing the sum of squares for treatments by the sum of squares for error.
D) dividing the degrees of freedom by each other.

A) 100
B) 95
C) 93
D) 92

A) SS _between
B) SS _within
C) SS _total
D) MS _error

A) the probability of at least one Type I error.
B) the probability of no Type I errors.
C) the number of Type I errors that you are likely to make.
D) the probability of a Type II error.

A) The difference "between groups" is significant by a one-tailed test of μ₁ μ ₂.
B) The difference "between groups" is not significant.
C) The difference "between groups" is significant.
D) We don't have enough information to draw a conclusion.

A) the number of groups.
B) the number of groups minus one.
C) the number of subjects per group.
D) the total number of subjects minus one.

A) Fisher's LSD.
B) Bonferroni.
C) Newmann Keuls.
D) Tukey test.

A)
B) η²
C) w ²
D) all of the above

A) Type I error
B) Type II error
C) mean squared error
D) random error

A) probability error rate
B) significance error rate
C) familywise error rate
D) test-retest error rate

A) Fisher's LSD test.
B) The Stroop test.
C) The Bonferroni test.
D) The Newman-Keuls test.

A)
B)
C)
D)

A) processing makes only minimal difference to recall.
B) old people don't learn anything.
C) just telling someone to learn a list of words doesn't work.
D) recall increases with the level of processing.

A) it is sometimes too conservative.
B) it is sometimes too liberal.
C) it is too difficult.
D) it relies on a non-normal distribution.

A) That MS_groups and MS_error would be roughly equal.
B) That MS_groups would be larger than MS_error.
C) That MS_error is larger than MS_groups.
D) That MS_error is close to zero.

A) the probability of at least one Type I error in a set of comparisons.
B) the probability of no Type I errors.
C) the number of Type I errors that you are likely to make.
D) the probability of a Type II error.

A) the r value would be .4.
B) 84% of the variability in running speed is attributed to shoe brand.
C) 16% of the variability in running speed is attributed to shoe brand.
D) most of the factors influencing running speed are contained in the brand of shoes worn by runners.

A) one-way ANOVA
B) factorial ANOVA
C) paired samples t -test
D) correlation

A) Fisher's LSD
B) Bonferroni procedure
C) factorial ANOVA
D) paired samples t-test

A) how different the group means are.
B) whether the dependent variable was measured incorrectly.
C) how much variability there is within each group.
D) whether the ANOVA is significant.

A) F Statistic
B) t Statistic
C) R Squared
D) both a and c

A) They decrease the probability of a Type I error.
B) They do not control familywise error rate.
C) It increases the probability of a Type I error.
D) They are more likely to be significant.

A) one way ANOVA
B) factorial ANOVA
C) paired samples t-test
D) correlation

A) .
B) η².
C) w ² .
D) all of the above

A) regression.
B) repeated-measures t-test.
C) Bonferroni test.
D) chi-square.

A) sophomores miss class more than juniors and seniors.
B) there is a difference in the mean number of times sophomores, juniors, and seniors miss class.
C) seniors miss class more than sophomores and juniors.
D) there is no difference between the groups.

A) η²
B) ω²
C)
D) all of the above

A)  computed on one or more pairs of groups.
B) η ² computed on all three groups.
C) w ²  computed on all three groups.
D) none of the above

A) it is not clear what it would mean if we could do so.
B) we don't know how to do so.
C) it does not address the questions we are likely to want to answer.
D) all of the above

A) it is more specific to individual treatments.
B) it is less biased than any other measure.
C) it pulls together information from all of the treatments.
D) It actually is a worse measure than the others.

A) the t test is limited to 2 samples.
B) the analysis of variance can handle multiple samples.
C) they test different hypotheses.
D) both a and b

A) μ ₁ = μ ₂
B) μ ₁ = μ ₂ = μ ₃ = μ ₄
C) μ ₁ = μ ₂ ≠ μ ₃ = μ ₄
D) μ ₁ ≠ μ ₂