Update 3-Power-calculations.md

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@ -5,8 +5,11 @@ Necessary library pwr, loads with library(pwr)
Necessary function: pwr.t2n.test Necessary function: pwr.t2n.test
See: https://www.statmethods.net/stats/power.html See: https://www.statmethods.net/stats/power.html
Optimistic: We reach everyone
Pessimistic: We reach 66% of treatment and control group.
## Year 1, pessimistic projections ## Year 1, pessimistic projections
With n-treatment=20, n-control = 20, power = 0.9,sig.level= 0.05, power = 0.9, minimal detectable effect = ? ith n-treatment=20, n-control = 20, power = 0.9,sig.level= 0.05, power = 0.9, minimal detectable effect in standard deviations (d) = ?
t test power calculation t test power calculation
@ -29,7 +32,7 @@ sig.level = 0.05
power = 0.9 power = 0.9
alternative = two.sided alternative = two.sided
Withn = ?, power = 0.9,sig.level= 0.05, power = 0.9, minimal detectable effect = 0.5 With n = ?, power = 0.9,sig.level= 0.05, power = 0.9, minimal detectable effect = 0.5
Two-sample t test power calculation Two-sample t test power calculation
@ -117,8 +120,8 @@ alternative = two.sided
## Population necessary to detect an effect size of 0.2 with significance level = 0.05 and power = 0.9 ## Population necessary to detect an effect size of 0.2 with significance level = 0.05 and power = 0.9
here the free variable was d= minimal detectable effect Here the free variable was d= minimal detectable effect
Withn = ?, power = 0.9,sig.level= 0.05, power = 0.9, minimal detectable effect = 0.2 With n = ?, power = 0.9,sig.level= 0.05, power = 0.9, minimal detectable effect = 0.2
Two-sample t test power calculation Two-sample t test power calculation
@ -174,3 +177,4 @@ NOTE: n is number in *each* group
## Conclusions. ## Conclusions.
Even after 4 years, under the most optimistic population projections (i.e., every participant answers our surveys every year, and 60 students who didn't get selected also do), we wouldn't have enough power to detect an effect size of 0.2 standard deviations with significance level = 0.05. However, it seems feasible to detect the kinds of effects which would justify the upward of $150.000 / year costs of ESPR within 3 years. The minimum effect which justifies the costs of ESPR should be determined beforehand, as should the axis along which we measure. I would also suggest to expand the RCT to SPARC once its feasibility has been tested at ESPR. Even after 4 years, under the most optimistic population projections (i.e., every participant answers our surveys every year, and 60 students who didn't get selected also do), we wouldn't have enough power to detect an effect size of 0.2 standard deviations with significance level = 0.05. However, it seems feasible to detect the kinds of effects which would justify the upward of $150.000 / year costs of ESPR within 3 years. The minimum effect which justifies the costs of ESPR should be determined beforehand, as should the axis along which we measure. I would also suggest to expand the RCT to SPARC once its feasibility has been tested at ESPR.