Module 3 Flashcards
(27 cards)
t or f: if the h0 is very unlikely, you can conclude that the difference/magnitude is large
false
Bayesian Stats
- alt to NHST
- argues that NHST logic is flawed
- in the data you calculate a Bayes factor (ratio of likelihood of alt hypothesis relative to likelihood of null hypothesis)
- 1=equal, <1=null more likely, >1=alt more likely (3=moderate/baseline, 10=strong)
raw effect size
- unstandardized regression coefficients are raw effect sizes
- the size of the difference between two means and treat it as an indication of magnitude
- works well if variable of interest is on a meaningful metric
standard effect sizes indicators in relation to t tests
- cohen’s d
- pearson’s r
cohen’s d
- effect size you can apply to a t test
- expresses magnitude as a standard difference between means
- percentage of the SD
- aka ds
cohens d for independent sample t test formula
ds=(x1-x2)/pooledS
S=standard deviation around first and second mean
pooled S (standard deviation) formula for use in cohens d formula
pooled S= √ (n1-1)s1^2+(n2-1)s2^2/(n1+n2-2)
t or f: ds (cohen’s d) has a minimum of 0 and a max of 10
false, a min of 0 (no difference) and no upper boundary
ex. 0.5=dif between means is half size of DV’s SD, 1=difference is just as big, 2=mean difference is twice as big as DV’s
ds size guidelines
- 0.2=small
- 0.5=med
-0.8=large
d(av) formula
- cohen’s d for repeated measures
d(av)=D_/Avg.S
formula for Avg.S in d(av) formula
Avg.S=(S1+S2)/2
S
standard deviation
d(rm) formula
- repeated measures effect size indicator that considers magnitude of correlation between observation sets
d(rm)= (M diff/√ s1^2+s2^2 x r x S1 x S2) x √ 2(1-r)
t or f: d(av) and d(rm) are both equally similar to d(s) exepct when r is low and the difference between standard deviations are large
flase, above is only true for d(av) not d(rm)
which d is considered overly conservative when r is large
d(rm)
because cohen’s d is a positively biased estimate of pop effect size (especially for small samples), what can be used to correct for this bias
Hedge’s g
pearson’s r coefficient
- used to quantify effect size
- determines point biserial correlation
r
- used to calculate strength and direction of correlation
point biserial correlation
- expressing relationship between dichotomous variable (membership in 1/2 groups) and cont variable (DV)
r^2 (pearson’s r)
- proportion of variance in DV accounted for by group membership
r ranges
- -1.00 = strong negative
- 0.00 = no relation
- 1.00 = strong positive
cohen’s guidelines for r
- 0.10 = small
- 0.30 = med
- 0.50 = large
it is necessary to make assumptions about _____ size when doing power calculations
effect
t or f: large effect sizes do not directly imply practical significance
- true
- durability of effect may be relevant
- cost/benefit analysis
- metric is hard to interpret
