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Power and Sample Size Adapted from: Boulder 2004 Benjamin Neale Shaun Purcell I HAVE THE POWER!!!

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Presentation on theme: "Power and Sample Size Adapted from: Boulder 2004 Benjamin Neale Shaun Purcell I HAVE THE POWER!!!"— Presentation transcript:

1 Power and Sample Size Adapted from: Boulder 2004 Benjamin Neale Shaun Purcell I HAVE THE POWER!!!

2 Overview Introduce Concept of Power via Correlation Coefficient (ρ) Example Introduce Concept of Power via Correlation Coefficient (ρ) Example Discuss Factors Contributing to Power Discuss Factors Contributing to Power Practical: Practical: Simulating data as a means of computing power Simulating data as a means of computing power Using Mx for Power Calculations Using Mx for Power Calculations

3 3 Simple example Investigate the linear relationship between two random variables X and Y:  =0 vs.  0 using the Pearson correlation coefficient. Sample subjects at random from population Sample subjects at random from population Measure X andY Measure X andY Calculate the measure of association  Calculate the measure of association  Test whether   0. Test whether   0.

4 4 How to Test   0 Assume data are normally distributed Define a null-hypothesis (  = 0) Choose an  level (usually.05) Use the (null) distribution of the test statistic associated with  =0 t=  √ [(N-2)/(1-  2 )]

5 5 How to Test   0 Sample N=40 r=.303, t=1.867, df=38, p=.06  =.05 Because observed p > , we fail to reject  = 0 Have we drawn the correct conclusion that p is genuinely zero?

6 6  = type I error rate probability of deciding  0 (while in truth  =0)  is often chosen to equal.05...why? DOGMA

7 7 N=40, r=0, nrep=1000, central t(38),  =0.05 (critical value 2.04)

8 8 Observed non-null distribution (  =.2) and null distribution

9 9 In 23% of tests that  =0, |t|>2.024 (  =0.05), and thus correctly conclude that  0. The probability of correctly rejecting the null-hypothesis (  =0) is 1- , known as the power.

10 Hypothesis Testing Correlation Coefficient hypotheses: Correlation Coefficient hypotheses: h o (null hypothesis) is ρ=0 h o (null hypothesis) is ρ=0 h a (alternative hypothesis) is ρ ≠ 0 h a (alternative hypothesis) is ρ ≠ 0 Two-sided test, where ρ > 0 or ρ 0 or ρ < 0 are one-sided Null hypothesis usually assumes no effect Null hypothesis usually assumes no effect Alternative hypothesis is the idea being tested Alternative hypothesis is the idea being tested

11 11 Summary of Possible Results H-0 trueH-0 false accept H-01-  reject H-0  1-   =type 1 error rate  =type 2 error rate 1-  =statistical power

12 Rejection of H 0 Non-rejection of H 0 H 0 true H A true STATISTICS R E A L I T Y Nonsignificant result (1-  ) Type II error at rate  Significant result (1-  ) Type I error at rate 

13 Power The probability of rejecting the null-hypothesis depends on: The probability of rejecting the null-hypothesis depends on: the significance criterion (  ) the significance criterion (  ) the sample size (N) the sample size (N) the effect size (NCP) the effect size (NCP) “The probability of detecting a given effect size in a population from a sample of size N, using significance criterion  ”

14 P(T)P(T) T alpha 0.05 Sampling distribution if H A were true Sampling distribution if H 0 were true   POWER = 1 -  Standard Case Effect Size (NCP)

15 P(T)P(T) T alpha 0.1 Sampling distribution if H A were true Sampling distribution if H 0 were true POWER = 1 -  ↑ Impact of less conservative Impact of less conservative   

16 P(T)P(T) T alpha 0.01 Sampling distribution if H A were true Sampling distribution if H 0 were true POWER = 1 -  ↓ Impact of more conservative Impact of more conservative   

17 P(T)P(T) T alpha 0.05   Impact of increased sample size Reduced variance of sampling distribution if H A is true Sampling distribution if H 0 is true POWER = 1 -  ↑

18 P(T)P(T) T alpha 0.05 Sampling distribution if H A were true Sampling distribution if H 0 were true   POWER = 1 -  ↑ Impact of increase in Effect Size Effect Size (NCP)↑

19 Summary: Factors affecting power Effect Size Effect Size Sample Size Sample Size Alpha Level Alpha Level Type of Data: Type of Data: Binary, Ordinal, Continuous Binary, Ordinal, Continuous Research Design Research Design

20 Uses of power calculations Planning a study Planning a study Possibly to reflect on ns trend result Possibly to reflect on ns trend result No need if significance is achieved No need if significance is achieved To determine chances of study success To determine chances of study success

21 Power Calculations via Simulation Simulate Data under theorized model Simulate Data under theorized model Calculate Statistics and Perform Test Calculate Statistics and Perform Test Given α, how many tests p < α Given α, how many tests p < α Power = (#hits)/(#tests) Power = (#hits)/(#tests)

22 Practical: Empirical Power 1 Simulate Data under a model online Simulate Data under a model online Fit an ACE model, and test for C Fit an ACE model, and test for C Collate fit statistics on board Collate fit statistics on board

23 Practical: Empirical Power 2 First get http://www.vipbg.vcu.edu/neale/gen619/power/p ower-raw.mx and put it into your directory First get http://www.vipbg.vcu.edu/neale/gen619/power/p ower-raw.mx and put it into your directory Second, open this script in Mx, and note both places where we must paste in the data Second, open this script in Mx, and note both places where we must paste in the data Third, simulate data (see next slide) Third, simulate data (see next slide) Fourth, fit the ACE model and then fit the AE submodel Fourth, fit the ACE model and then fit the AE submodel

24 Practical: Empirical Power 3 Simulation Conditions Simulation Conditions 30% A 2 20% C 2 50% E 2 30% A 2 20% C 2 50% E 2 Input: Input: A 0.5477 C of 0.4472 E of 0.7071 A 0.5477 C of 0.4472 E of 0.7071 350 MZ 350 DZ 350 MZ 350 DZ Simulate and use “Space Delimited” option at Simulate and use “Space Delimited” option at http://statgen.iop.kcl.ac.uk/workshop/unisim.html or click here in slide show mode http://statgen.iop.kcl.ac.uk/workshop/unisim.html or click here in slide show modehere Click submit after filling in the fields and you will get a page of data Click submit after filling in the fields and you will get a page of data

25 Practical: Empirical Power 4 With the data page, use ctrl-a to select the data, control-c to copy, switch to Mx (e.g. with alt-tab) and in Mx control-v to paste in both the MZ and DZ groups. With the data page, use ctrl-a to select the data, control-c to copy, switch to Mx (e.g. with alt-tab) and in Mx control-v to paste in both the MZ and DZ groups. Run the ace.mx script with the data pasted in and modify it to run the AE model. Run the ace.mx script with the data pasted in and modify it to run the AE model. Report the -2log-likelihoods on the whiteboard Report the -2log-likelihoods on the whiteboard Optionally, keep a record of A, C, and E estimates of the first model, and the A and E estimates of the second model Optionally, keep a record of A, C, and E estimates of the first model, and the A and E estimates of the second model

26 Simulation of other types of data Use SAS/R/Matlab/Mathematica Use SAS/R/Matlab/Mathematica Any decent random number generator will do Any decent random number generator will do See http://www.vipbg.vcu.edu/~neale/gen619/p ower/sim1.sas See http://www.vipbg.vcu.edu/~neale/gen619/p ower/sim1.sas http://www.vipbg.vcu.edu/~neale/gen619/p ower/sim1.sas http://www.vipbg.vcu.edu/~neale/gen619/p ower/sim1.sas

27 27 R R is in your future R is in your future Can do it manually with rnorm Can do it manually with rnorm Easier to use mvrnorm Easier to use mvrnorm runmx at Matt Keller’s site: runmx at Matt Keller’s site: http://www.matthewckeller.com/html/mx-r.html http://www.matthewckeller.com/html/mx-r.html http://www.matthewckeller.com/html/mx-r.html 27 library (MASS) mvrnorm(n=100,c(1,1),matrix(c(1,.5,.5,1),2,2),empirical=FALSE)

28 Mathematica Example In[32]:= (mu={1,2,3,4}; sigma={{1,1/2,1/3,1/4},{1/2,1/3,1/4,1/5},{1/3,1/4,1/5,1/6},{1/4,1/5,1/6, 1/7}}; Timing[Table[Random[MultinormalDistribution[mu,sigma]],{1000}]][[1]]) Out[32]= 1.1 Second In[33]:= Timing[RandomArray[MultinormalDistribution[mu,sigma],1000]][[1]] Out[33]= 0.04 Second In[37]:= TableForm[RandomArray[MultinormalDistribution[mu,sigma],10]] Obtain mathematica from VCU http://www.ts.vcu.edu/faq/stats/mathematica.html http://www.ts.vcu.edu/faq/stats/mathematica.html

29 Theoretical Power Calculations Based on Stats, rather than Simulations Based on Stats, rather than Simulations Can be calculated by hand sometimes, but Mx does it for us Can be calculated by hand sometimes, but Mx does it for us Note that sample size and alpha-level are the only things we can change, but can assume different effect sizes Note that sample size and alpha-level are the only things we can change, but can assume different effect sizes Mx gives us the relative power levels at the alpha specified for different sample sizes Mx gives us the relative power levels at the alpha specified for different sample sizes

30 Theoretical Power Calculations We will use the power.mx script to look at the sample size necessary for different power levels We will use the power.mx script to look at the sample size necessary for different power levels In Mx, power calculations can be computed in 2 ways: In Mx, power calculations can be computed in 2 ways: Using Covariance Matrices (We Do This One) Using Covariance Matrices (We Do This One) Requiring an initial dataset to generate a likelihood so that we can use a chi-square test Requiring an initial dataset to generate a likelihood so that we can use a chi-square test

31 Power.mx 1 ! Simulate the data ! 30% additive genetic ! 20% common environment ! 50% nonshared environment #NGroups 3 G1: model parameters Calculation Begin Matrices; X lower 1 1 fixed Y lower 1 1 fixed Z lower 1 1 fixed End Matrices; Matrix X 0.5477 Matrix Y 0.4472 Matrix Z 0.7071 Begin Algebra; A = X*X' ; C = Y*Y' ; E = Z*Z' ; End Algebra; End

32 Power.mx 2 G2: MZ twin pairs Calculation Matrices = Group 1 Covariances A+C+E|A+C _ A+C|A+C+E / Options MX%E=mzsim.cov End G3: DZ twin pairs Calculation Matrices = Group 1 H Full 1 1 H Full 1 1 Covariances A+C+E|H@A+C _ H@A+C|A+C+E / Matrix H 0.5 Options MX%E=dzsim.cov End

33 Power.mx 3 ! Second part of script ! Fit the wrong model to the simulated data ! to calculate power #NGroups 3 G1 : model parameters Calculation Begin Matrices; X lower 1 1 free Y lower 1 1 fixed Z lower 1 1 free End Matrices; Begin Algebra; A = X*X' ; C = Y*Y' ; E = Z*Z' ; End Algebra; End

34 Power.mx 4 G2 : MZ twins Data NInput_vars=2 NObservations=350 CMatrix Full File=mzsim.cov Matrices= Group 1 Covariances A+C+E|A+C _ A+C | A+C+E / Option RSiduals End G3 : DZ twins Data NInput_vars=2 NObservations=350 CMatrix Full File=dzsim.cov Matrices= Group 1 H Full 1 1 H Full 1 1 Covariances A+C+E|H@A+C _ H@A+C | A+C+E / Matix H 0.5 Option RSiduals ! Power for alpha = 0.05 and 1 df Option Power= 0.05,1 End

35 35 Model Identification Necessary Conditions Necessary Conditions Sufficient Conditions Sufficient Conditions Algebraic Tests Algebraic Tests Empirical Tests Empirical Tests 35

36 36 Necessary Conditions Number of Parameters < or = Number of Statistics Number of Parameters < or = Number of Statistics Structural Equation Model usually count variances & covariances to identify variance components Structural Equation Model usually count variances & covariances to identify variance components What is the number of statistics/parameters in a univariate ACE model? Bivariate? What is the number of statistics/parameters in a univariate ACE model? Bivariate? 36

37 37 Sufficient Conditions No general sufficient conditions for SEM No general sufficient conditions for SEM Special case: ACE model Special case: ACE model Distinct Statistics (i.e. have different predicted values Distinct Statistics (i.e. have different predicted values VP = a2 + c2 + e2 VP = a2 + c2 + e2 CMZ = a2 + c2 CMZ = a2 + c2 CDZ =.5 a2 + c2 CDZ =.5 a2 + c2 37

38 38 Sufficient Conditions 2 Arrange in matrix form Arrange in matrix form 1 1 1 a2 VP 1 1 1 a2 VP 1 1 0 c2 = CMZ 1 1 0 c2 = CMZ.5 1 0 e2 CDZ.5 1 0 e2 CDZ A x = b A x = b If A can be inverted then can find A -1 b If A can be inverted then can find A -1 b 38

39 39 Sufficient Conditions 3 39 Solve ACE modelCalc ng=1Begin Matrices; A full 3 3 b full 3 1End Matrices;Matrix A1 1 11 1 0.5 1 0Labels Col A A C ELabels Row A VP CMZ CDZMatrix b ! Data, essentially1.8.5Labels Col B StatisticLabels Row B VP CMZ CDZBegin Algebra; C = A~; x = A~*b;End Algebra;Labels Row x A C EEnd

40 40 Sufficient Conditions 4 What if not soluble by inversion? What if not soluble by inversion? Empirical: Empirical: 1 Pick set of parameter values T 1 1 Pick set of parameter values T 1 2 Simulate data 2 Simulate data 3 Fit model to data starting at T 2 (not T 1 ) 3 Fit model to data starting at T 2 (not T 1 ) 4 Repeat and look for solutions to step 3 that are perfect but have estimates not equal to T 1 4 Repeat and look for solutions to step 3 that are perfect but have estimates not equal to T 1 If equally good solution but different values, reject identified model hypothesis If equally good solution but different values, reject identified model hypothesis 40

41 Conclusion Power calculations relatively simple to do Power calculations relatively simple to do Curse of dimensionality Curse of dimensionality Different for raw vs summary statistics Different for raw vs summary statistics Simulation can be done many ways Simulation can be done many ways No substitute for research design No substitute for research design

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