Summary of Discovering statistics using IBM SPSS statistics by Field - 5th edition
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Statistics
Chapter 15
Repeated measures designs
Repeated measures: when the same entities participate in all conditions of an experiment or provide data at multiple time points.
Repeated measures can also be considered as a variation of the general linear model.
For example.
Ygi = b0i +b1iXgi +Ɛgi
b0i = b0 + u0i
b1i = b1 + u1i
Ygi for outcome g within person i from the specific predictor Xgi with the error Ɛgi
g is the level of treatment condition
i for the individuals
u0i for the deviation of the individual’s intercept from the group-level intercept
The way that people typically handle repeated measures in IBM SPSS is to use a repeated-measures ANOVA approach.
The assumption of sphericity
The assumption that permits us to use a simpler model to analyse repeated-measures data is sphericity.
Sphericity: assuming that the relationship between scores in pairs of treatment conditions is similar.
It is a form of compound symmetry: holds true when both the variances across conditions are equal and the covariances between pairs of conditions are equal.
We assume that the variation within conditions is similar and that no two conditions are any more dependent than any other two.
Sphericity is a more general, less restrictive form of compound symmetry and refers to the equality of variances of the differences between treatment levels.
For example:
varianceA-B = varianceA-C = varianceB-C
Assessing the severity of departures from sphericity
Mauchly’s test: assesses the hypothesis that the variances of the differences between conditions are equal.
If the test is statistically significant, it implies that there are significant differences between the variances of differences and, therefore, sphericity is not met.
If it is not significant, the implication is that the variances of differences are roughly equal and sphericity is met.
It depends upon sample size.
What’s the effect of violating the assumption of sphericity?
A lack of sphericity creates a loss of power and an F-statistic that doesn’t have the distribution that it’s supposed to have.
It also causes some complications for post hoc tests.
What do you do if you violate sphericity?
Adjust the degrees of freedom of any F-statistic affected.
The greater the violation of sphericity, the smaller the degrees of freedom become.
Or fit the multilevel model or use a MANOVA
In a repeated-measures design the effect of the experiment is shown up in the within-participant variance.
We look for the experimental effect (the model sum of squares) within the individual rather than within the group.
The types of variances are the same as in independent designs: the total sum of squares, a model sum of squares, and residual sum of squares.
In repeated-measures designs the model and residual of squares are both part of the within-participant variance.
The total sum of squares, SST
SST = s2Grand(N-1)
The grand variance is the variance of all scores when we ignore the group to which they belong. We treat data as one big group
Df = N-1
Within-participant sum of squares SSW
A within-participant variance component, which represents individual differences within participants.
SSW = s2entitiy1(n1-1) + s2entitiy2(n2-1) + s2entitiy3(n3-1) + … + s2entitiyn(nn-1)
Looking at the variation in each individual’s score and then adding these variances for all the entities in the study. The ns represents the number of scores within the person.
The df = n-1
to get the total degrees of freedom we add the df’s for all participants.
The model sum of squares SSM
How much variance is explained by our manipulation and how much is not.
SSM = Σkg-1ng(meang-meangrand)2
df = k -1
Residual sum of squares SSR
how much of the variation cannot be explained by the model.
The amount of variation caused by extraneous factors outside experimental control.
SSR = SSW-SSM
dfR= dfW-dfM
The mean squares MSM
the mean squares represents the average variation explained by the model
MSM = SSM/dfM
MSR = SSR/dfR
The F-statistic
The F-statistic is the ratio of variation explained by the model and the variation explained by unsystematic factors.
F = MSM/MSR
The experimental effect on performance to the effect of unmeasured factors.
If the values is greater than 1, it indicates that the experimental manipulation had some effect above and beyond the effect of unmeasured factors.
The between-participant sum of squares
SST = SSB-SSW
SSB = SST-SSW
SSB is the individual differences between cases.
All sources of potential bias in chapter 6 apply.
Using the ANOVA approach, the assumption of independence is replaced by assumptions about the relationships between differences scores (sphericity)
In the multilevel approach, sphericity isn’t required.
If assumptions are not met, there is a robust variant of one-way repeated-measures ANOVA.
The best measure of the overall effect size is omega squared ω2.
ω2 = ((k-1)/nk) (MSM – MSR) / (MSR + ((MSB – MSR)/k) +((k-1)/nk) (MSM – MSR))
MSB = SSB/dfB = SSB/(N-1)
Effect size for the contrasts
r = square root ( (F(1,dfR))/ (F(1,dfR) +dfR) )
F, the correct degrees of freedom, p and effect size.
Effect sizes are more useful when they describe a focused effect, so calculate effect sizes for you contrasts in factorial designs.
We have multiple effects to report and we need to report corrected degrees of freedom for each, and these effects might have different degrees of freedom.
F, degrees of freedom, p and effect size.
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