latent.regression.em.raschtype: Latent Regression Model for the Generalized Logistic Item...
In sirt: Supplementary Item Response Theory Models
View source: R/latent.regression.em.raschtype.R
latent.regression.em.raschtype R Documentation
Latent Regression Model for the Generalized
Logistic Item Response Model and the Linear Model for Normal Responses
Description
This function estimates a unidimensional latent regression model if
a likelihood is specified, parameters from the generalized
item response model (Stukel, 1988) or a mean and a standard error
estimate for individual scores is provided as input.
Item parameters are treated as fixed in the estimation.
Usage
latent.regression.em.raschtype(data=NULL, f.yi.qk=NULL, X,
weights=rep(1, nrow(X)), beta.init=rep(0,ncol(X)),
sigma.init=1, b=rep(0,ncol(X)), a=rep(1,length(b)),
c=rep(0, length(b)), d=rep(1, length(b)), alpha1=0, alpha2=0,
max.parchange=1e-04, theta.list=seq(-5, 5, len=20),
maxiter=300, progress=TRUE )
latent.regression.em.normal(y, X, sig.e, weights=rep(1, nrow(X)),
beta.init=rep(0, ncol(X)), sigma.init=1, max.parchange=1e-04,
maxiter=300, progress=TRUE)
## S3 method for class 'latent.regression'
summary(object,...)
Arguments
data
An N \times I data frame of dichotomous item responses.
If no data frame is supplied, then a user can input the individual
likelihood f.yi.qk.
f.yi.qk
An optional matrix which contains the individual likelihood.
This matrix is produced by rasch.mml2 or
rasch.copula2. The use of this argument allows the
estimation of the latent regression model independent of the
parameters of the used item response model.
X
An N \times K matrix of K covariates in the latent
regression model. Note that the intercept (i.e. a vector of ones)
must be included in X.
weights
Student weights (optional).
beta.init
Initial regression coefficients (optional).
sigma.init
Initial residual standard deviation (optional).
b
Item difficulties (optional). They must only be provided
if the likelihood f.yi.qk is not given as an input.
a
Item discriminations (optional).
c
Guessing parameter (lower asymptotes) (optional).
d
One minus slipping parameter (upper asymptotes) (optional).
alpha1
Upper tail parameter \alpha_1 in the generalized logistic item response model.
Default is 0.
alpha2
Lower tail parameter \alpha_2 parameter in the generalized
logistic item response model. Default is 0.
max.parchange
Maximum change in regression parameters
theta.list
Grid of person ability where theta is evaluated
maxiter
Maximum number of iterations
progress
An optional logical indicating whether computation
progress should be displayed.
y
Individual scores
sig.e
Standard errors for individual scores
object
Object of class latent.regression
...
Further arguments to be passed
Details
In the output Regression Parameters
the fraction of missing information (fmi) is reported
which is the increase of variance in regression
parameter estimates because ability is defined as
a latent variable. The effective sample size pseudoN.latent
corresponds to a sample size when the ability would be
available with a reliability of one.
Value
A list with following entries
iterations
Number of iterations needed
maxiter
Maximal number of iterations
max.parchange
Maximum change in parameter estimates
coef
Coefficients
summary.coef
Summary of regression coefficients
sigma
Estimate of residual standard deviation
vcov.simple
Covariance parameters of estimated parameters
(simplified version)
vcov.latent
Covariance parameters of estimated parameters
which accounts for latent ability
post
Individual posterior distribution
EAP
Individual EAP estimates
SE.EAP
Standard error estimates of EAP
explvar
Explained variance in latent regression
totalvar
Total variance in latent regression
rsquared
Explained variance R^2 in latent regression
Note
Using the defaults in a, c, d,
alpha1 and alpha2 corresponds to the
Rasch model.
References
Adams, R., & Wu. M. (2007). The mixed-coefficients multinomial
logit model: A generalized form of the Rasch model.
In M. von Davier & C. H. Carstensen (Eds.). Multivariate and mixture
distribution Rasch models: Extensions and applications (pp. 57-76).
New York: Springer.
\Sexpr[results=rd]{tools:::Rd_expr_doi("10.1007/978-0-387-49839-3_4")}
Mislevy, R. J. (1991). Randomization-based inference about latent variables
from complex samples. Psychometrika, 56(2), 177-196.
\Sexpr[results=rd]{tools:::Rd_expr_doi("10.1007/BF02294457")}
Stukel, T. A. (1988). Generalized logistic models.
Journal of the American Statistical Association, 83(402), 426-431.
\Sexpr[results=rd]{tools:::Rd_expr_doi("10.1080/01621459.1988.10478613")}
See Also
See also plausible.value.imputation.raschtype
for plausible value imputation of generalized logistic
item type models.
Examples
#############################################################################
# EXAMPLE 1: PISA Reading | Rasch model for dichotomous data
#############################################################################
data(data.pisaRead, package="sirt")
dat <- data.pisaRead$data
items <- grep("R", colnames(dat))
# define matrix of covariates
X <- cbind( 1, dat[, c("female","hisei","migra" ) ] )
#***
# Model 1: Latent regression model in the Rasch model
# estimate Rasch model
mod1 <- sirt::rasch.mml2( dat[,items] )
# latent regression model
lm1 <- sirt::latent.regression.em.raschtype( data=dat[,items ], X=X, b=mod1$item$b )
## Not run:
#***
# Model 2: Latent regression with generalized link function
# estimate alpha parameters for link function
mod2 <- sirt::rasch.mml2( dat[,items], est.alpha=TRUE)
# use model estimated likelihood for latent regression model
lm2 <- sirt::latent.regression.em.raschtype( f.yi.qk=mod2$f.yi.qk,
X=X, theta.list=mod2$theta.k)
#***
# Model 3: Latent regression model based on Rasch copula model
testlets <- paste( data.pisaRead$item$testlet)
itemclusters <- match( testlets, unique(testlets) )
# estimate Rasch copula model
mod3 <- sirt::rasch.copula2( dat[,items], itemcluster=itemclusters )
# use model estimated likelihood for latent regression model
lm3 <- sirt::latent.regression.em.raschtype( f.yi.qk=mod3$f.yi.qk,
X=X, theta.list=mod3$theta.k)
#############################################################################
# EXAMPLE 2: Simulated data according to the Rasch model
#############################################################################
set.seed(899)
I <- 21 # number of items
b <- seq(-2,2, len=I) # item difficulties
n <- 2000 # number of students
# simulate theta and covariates
theta <- stats::rnorm( n )
x <- .7 * theta + stats::rnorm( n, .5 )
y <- .2 * x+ .3*theta + stats::rnorm( n, .4 )
dfr <- data.frame( theta, 1, x, y )
# simulate Rasch model
dat1 <- sirt::sim.raschtype( theta=theta, b=b )
# estimate latent regression
mod <- sirt::latent.regression.em.raschtype( data=dat1, X=dfr[,-1], b=b )
## Regression Parameters
##
## est se.simple se t p beta fmi N.simple pseudoN.latent
## X1 -0.2554 0.0208 0.0248 -10.2853 0 0.0000 0.2972 2000 1411.322
## x 0.4113 0.0161 0.0193 21.3037 0 0.4956 0.3052 2000 1411.322
## y 0.1715 0.0179 0.0213 8.0438 0 0.1860 0.2972 2000 1411.322
##
## Residual Variance=0.685
## Explained Variance=0.3639
## Total Variance=1.049
## R2=0.3469
# compare with linear model (based on true scores)
summary( stats::lm( theta ~ x + y, data=dfr ) )
## Coefficients:
## Estimate Std. Error t value Pr(>|t|)
## (Intercept) -0.27821 0.01984 -14.02 <2e-16 ***
## x 0.40747 0.01534 26.56 <2e-16 ***
## y 0.18189 0.01704 10.67 <2e-16 ***
## ---
##
## Residual standard error: 0.789 on 1997 degrees of freedom
## Multiple R-squared: 0.3713, Adjusted R-squared: 0.3707
#***********
# define guessing parameters (lower asymptotes) and
# upper asymptotes ( 1 minus slipping parameters)
cI <- rep(.2, I) # all items get a guessing parameter of .2
cI[ c(7,9) ] <- .25 # 7th and 9th get a guessing parameter of .25
dI <- rep( .95, I ) # upper asymptote of .95
dI[ c(7,11) ] <- 1 # 7th and 9th item have an asymptote of 1
# latent regression model
mod1 <- sirt::latent.regression.em.raschtype( data=dat1, X=dfr[,-1],
b=b, c=cI, d=dI )
## Regression Parameters
##
## est se.simple se t p beta fmi N.simple pseudoN.latent
## X1 -0.7929 0.0243 0.0315 -25.1818 0 0.0000 0.4044 2000 1247.306
## x 0.5025 0.0188 0.0241 20.8273 0 0.5093 0.3936 2000 1247.306
## y 0.2149 0.0209 0.0266 8.0850 0 0.1960 0.3831 2000 1247.306
##
## Residual Variance=0.9338
## Explained Variance=0.5487
## Total Variance=1.4825
## R2=0.3701
#############################################################################
# EXAMPLE 3: Measurement error in dependent variable
#############################################################################
set.seed(8766)
N <- 4000 # number of persons
X <- stats::rnorm(N) # independent variable
Z <- stats::rnorm(N) # independent variable
y <- .45 * X + .25 * Z + stats::rnorm(N) # dependent variable true score
sig.e <- stats::runif( N, .5, .6 ) # measurement error standard deviation
yast <- y + stats::rnorm( N, sd=sig.e ) # dependent variable measured with error
#****
# Model 1: Estimation with latent.regression.em.raschtype using
# individual likelihood
# define theta grid for evaluation of density
theta.list <- mean(yast) + stats::sd(yast) * seq( - 5, 5, length=21)
# compute individual likelihood
f.yi.qk <- stats::dnorm( outer( yast, theta.list, "-" ) / sig.e )
f.yi.qk <- f.yi.qk / rowSums(f.yi.qk)
# define predictor matrix
X1 <- as.matrix(data.frame( "intercept"=1, "X"=X, "Z"=Z ))
# latent regression model
res <- sirt::latent.regression.em.raschtype( f.yi.qk=f.yi.qk,
X=X1, theta.list=theta.list)
## Regression Parameters
##
## est se.simple se t p beta fmi N.simple pseudoN.latent
## intercept 0.0112 0.0157 0.0180 0.6225 0.5336 0.0000 0.2345 4000 3061.998
## X 0.4275 0.0157 0.0180 23.7926 0.0000 0.3868 0.2350 4000 3061.998
## Z 0.2314 0.0156 0.0178 12.9868 0.0000 0.2111 0.2349 4000 3061.998
##
## Residual Variance=0.9877
## Explained Variance=0.2343
## Total Variance=1.222
## R2=0.1917
#****
# Model 2: Estimation with latent.regression.em.normal
res2 <- sirt::latent.regression.em.normal( y=yast, sig.e=sig.e, X=X1)
## Regression Parameters
##
## est se.simple se t p beta fmi N.simple pseudoN.latent
## intercept 0.0112 0.0157 0.0180 0.6225 0.5336 0.0000 0.2345 4000 3062.041
## X 0.4275 0.0157 0.0180 23.7927 0.0000 0.3868 0.2350 4000 3062.041
## Z 0.2314 0.0156 0.0178 12.9870 0.0000 0.2111 0.2349 4000 3062.041
##
## Residual Variance=0.9877
## Explained Variance=0.2343
## Total Variance=1.222
## R2=0.1917
## -> Results between Model 1 and Model 2 are identical because they use
## the same input.
#***
# Model 3: Regression model based on true scores y
mod3 <- stats::lm( y ~ X + Z )
summary(mod3)
## Coefficients:
## Estimate Std. Error t value Pr(>|t|)
## (Intercept) 0.02364 0.01569 1.506 0.132
## X 0.42401 0.01570 27.016 <2e-16 ***
## Z 0.23804 0.01556 15.294 <2e-16 ***
## Residual standard error: 0.9925 on 3997 degrees of freedom
## Multiple R-squared: 0.1923, Adjusted R-squared: 0.1919
## F-statistic: 475.9 on 2 and 3997 DF, p-value: < 2.2e-16
#***
# Model 4: Regression model based on observed scores yast
mod4 <- stats::lm( yast ~ X + Z )
summary(mod4)
## Coefficients:
## Estimate Std. Error t value Pr(>|t|)
## (Intercept) 0.01101 0.01797 0.613 0.54
## X 0.42716 0.01797 23.764 <2e-16 ***
## Z 0.23174 0.01783 13.001 <2e-16 ***
## Residual standard error: 1.137 on 3997 degrees of freedom
## Multiple R-squared: 0.1535, Adjusted R-squared: 0.1531
## F-statistic: 362.4 on 2 and 3997 DF, p-value: < 2.2e-16
## End(Not run)
sirt documentation built on May 29, 2024, 8:43 a.m.
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View source: R/latent.regression.em.raschtype.R
| latent.regression.em.raschtype | R Documentation |
Latent Regression Model for the Generalized Logistic Item Response Model and the Linear Model for Normal Responses
Description
This function estimates a unidimensional latent regression model if a likelihood is specified, parameters from the generalized item response model (Stukel, 1988) or a mean and a standard error estimate for individual scores is provided as input. Item parameters are treated as fixed in the estimation.
Usage
latent.regression.em.raschtype(data=NULL, f.yi.qk=NULL, X,
weights=rep(1, nrow(X)), beta.init=rep(0,ncol(X)),
sigma.init=1, b=rep(0,ncol(X)), a=rep(1,length(b)),
c=rep(0, length(b)), d=rep(1, length(b)), alpha1=0, alpha2=0,
max.parchange=1e-04, theta.list=seq(-5, 5, len=20),
maxiter=300, progress=TRUE )
latent.regression.em.normal(y, X, sig.e, weights=rep(1, nrow(X)),
beta.init=rep(0, ncol(X)), sigma.init=1, max.parchange=1e-04,
maxiter=300, progress=TRUE)
## S3 method for class 'latent.regression'
summary(object,...)
Arguments
data |
An |
f.yi.qk |
An optional matrix which contains the individual likelihood.
This matrix is produced by |
X |
An |
weights |
Student weights (optional). |
beta.init |
Initial regression coefficients (optional). |
sigma.init |
Initial residual standard deviation (optional). |
b |
Item difficulties (optional). They must only be provided
if the likelihood |
a |
Item discriminations (optional). |
c |
Guessing parameter (lower asymptotes) (optional). |
d |
One minus slipping parameter (upper asymptotes) (optional). |
alpha1 |
Upper tail parameter |
alpha2 |
Lower tail parameter |
max.parchange |
Maximum change in regression parameters |
theta.list |
Grid of person ability where theta is evaluated |
maxiter |
Maximum number of iterations |
progress |
An optional logical indicating whether computation progress should be displayed. |
y |
Individual scores |
sig.e |
Standard errors for individual scores |
object |
Object of class |
... |
Further arguments to be passed |
Details
In the output Regression Parameters
the fraction of missing information (fmi) is reported
which is the increase of variance in regression
parameter estimates because ability is defined as
a latent variable. The effective sample size pseudoN.latent
corresponds to a sample size when the ability would be
available with a reliability of one.
Value
A list with following entries
iterations |
Number of iterations needed |
maxiter |
Maximal number of iterations |
max.parchange |
Maximum change in parameter estimates |
coef |
Coefficients |
summary.coef |
Summary of regression coefficients |
sigma |
Estimate of residual standard deviation |
vcov.simple |
Covariance parameters of estimated parameters (simplified version) |
vcov.latent |
Covariance parameters of estimated parameters which accounts for latent ability |
post |
Individual posterior distribution |
EAP |
Individual EAP estimates |
SE.EAP |
Standard error estimates of EAP |
explvar |
Explained variance in latent regression |
totalvar |
Total variance in latent regression |
rsquared |
Explained variance |
Note
Using the defaults in a, c, d,
alpha1 and alpha2 corresponds to the
Rasch model.
References
Adams, R., & Wu. M. (2007). The mixed-coefficients multinomial logit model: A generalized form of the Rasch model. In M. von Davier & C. H. Carstensen (Eds.). Multivariate and mixture distribution Rasch models: Extensions and applications (pp. 57-76). New York: Springer. \Sexpr[results=rd]{tools:::Rd_expr_doi("10.1007/978-0-387-49839-3_4")}
Mislevy, R. J. (1991). Randomization-based inference about latent variables from complex samples. Psychometrika, 56(2), 177-196. \Sexpr[results=rd]{tools:::Rd_expr_doi("10.1007/BF02294457")}
Stukel, T. A. (1988). Generalized logistic models. Journal of the American Statistical Association, 83(402), 426-431. \Sexpr[results=rd]{tools:::Rd_expr_doi("10.1080/01621459.1988.10478613")}
See Also
See also plausible.value.imputation.raschtype
for plausible value imputation of generalized logistic
item type models.
Examples
#############################################################################
# EXAMPLE 1: PISA Reading | Rasch model for dichotomous data
#############################################################################
data(data.pisaRead, package="sirt")
dat <- data.pisaRead$data
items <- grep("R", colnames(dat))
# define matrix of covariates
X <- cbind( 1, dat[, c("female","hisei","migra" ) ] )
#***
# Model 1: Latent regression model in the Rasch model
# estimate Rasch model
mod1 <- sirt::rasch.mml2( dat[,items] )
# latent regression model
lm1 <- sirt::latent.regression.em.raschtype( data=dat[,items ], X=X, b=mod1$item$b )
## Not run:
#***
# Model 2: Latent regression with generalized link function
# estimate alpha parameters for link function
mod2 <- sirt::rasch.mml2( dat[,items], est.alpha=TRUE)
# use model estimated likelihood for latent regression model
lm2 <- sirt::latent.regression.em.raschtype( f.yi.qk=mod2$f.yi.qk,
X=X, theta.list=mod2$theta.k)
#***
# Model 3: Latent regression model based on Rasch copula model
testlets <- paste( data.pisaRead$item$testlet)
itemclusters <- match( testlets, unique(testlets) )
# estimate Rasch copula model
mod3 <- sirt::rasch.copula2( dat[,items], itemcluster=itemclusters )
# use model estimated likelihood for latent regression model
lm3 <- sirt::latent.regression.em.raschtype( f.yi.qk=mod3$f.yi.qk,
X=X, theta.list=mod3$theta.k)
#############################################################################
# EXAMPLE 2: Simulated data according to the Rasch model
#############################################################################
set.seed(899)
I <- 21 # number of items
b <- seq(-2,2, len=I) # item difficulties
n <- 2000 # number of students
# simulate theta and covariates
theta <- stats::rnorm( n )
x <- .7 * theta + stats::rnorm( n, .5 )
y <- .2 * x+ .3*theta + stats::rnorm( n, .4 )
dfr <- data.frame( theta, 1, x, y )
# simulate Rasch model
dat1 <- sirt::sim.raschtype( theta=theta, b=b )
# estimate latent regression
mod <- sirt::latent.regression.em.raschtype( data=dat1, X=dfr[,-1], b=b )
## Regression Parameters
##
## est se.simple se t p beta fmi N.simple pseudoN.latent
## X1 -0.2554 0.0208 0.0248 -10.2853 0 0.0000 0.2972 2000 1411.322
## x 0.4113 0.0161 0.0193 21.3037 0 0.4956 0.3052 2000 1411.322
## y 0.1715 0.0179 0.0213 8.0438 0 0.1860 0.2972 2000 1411.322
##
## Residual Variance=0.685
## Explained Variance=0.3639
## Total Variance=1.049
## R2=0.3469
# compare with linear model (based on true scores)
summary( stats::lm( theta ~ x + y, data=dfr ) )
## Coefficients:
## Estimate Std. Error t value Pr(>|t|)
## (Intercept) -0.27821 0.01984 -14.02 <2e-16 ***
## x 0.40747 0.01534 26.56 <2e-16 ***
## y 0.18189 0.01704 10.67 <2e-16 ***
## ---
##
## Residual standard error: 0.789 on 1997 degrees of freedom
## Multiple R-squared: 0.3713, Adjusted R-squared: 0.3707
#***********
# define guessing parameters (lower asymptotes) and
# upper asymptotes ( 1 minus slipping parameters)
cI <- rep(.2, I) # all items get a guessing parameter of .2
cI[ c(7,9) ] <- .25 # 7th and 9th get a guessing parameter of .25
dI <- rep( .95, I ) # upper asymptote of .95
dI[ c(7,11) ] <- 1 # 7th and 9th item have an asymptote of 1
# latent regression model
mod1 <- sirt::latent.regression.em.raschtype( data=dat1, X=dfr[,-1],
b=b, c=cI, d=dI )
## Regression Parameters
##
## est se.simple se t p beta fmi N.simple pseudoN.latent
## X1 -0.7929 0.0243 0.0315 -25.1818 0 0.0000 0.4044 2000 1247.306
## x 0.5025 0.0188 0.0241 20.8273 0 0.5093 0.3936 2000 1247.306
## y 0.2149 0.0209 0.0266 8.0850 0 0.1960 0.3831 2000 1247.306
##
## Residual Variance=0.9338
## Explained Variance=0.5487
## Total Variance=1.4825
## R2=0.3701
#############################################################################
# EXAMPLE 3: Measurement error in dependent variable
#############################################################################
set.seed(8766)
N <- 4000 # number of persons
X <- stats::rnorm(N) # independent variable
Z <- stats::rnorm(N) # independent variable
y <- .45 * X + .25 * Z + stats::rnorm(N) # dependent variable true score
sig.e <- stats::runif( N, .5, .6 ) # measurement error standard deviation
yast <- y + stats::rnorm( N, sd=sig.e ) # dependent variable measured with error
#****
# Model 1: Estimation with latent.regression.em.raschtype using
# individual likelihood
# define theta grid for evaluation of density
theta.list <- mean(yast) + stats::sd(yast) * seq( - 5, 5, length=21)
# compute individual likelihood
f.yi.qk <- stats::dnorm( outer( yast, theta.list, "-" ) / sig.e )
f.yi.qk <- f.yi.qk / rowSums(f.yi.qk)
# define predictor matrix
X1 <- as.matrix(data.frame( "intercept"=1, "X"=X, "Z"=Z ))
# latent regression model
res <- sirt::latent.regression.em.raschtype( f.yi.qk=f.yi.qk,
X=X1, theta.list=theta.list)
## Regression Parameters
##
## est se.simple se t p beta fmi N.simple pseudoN.latent
## intercept 0.0112 0.0157 0.0180 0.6225 0.5336 0.0000 0.2345 4000 3061.998
## X 0.4275 0.0157 0.0180 23.7926 0.0000 0.3868 0.2350 4000 3061.998
## Z 0.2314 0.0156 0.0178 12.9868 0.0000 0.2111 0.2349 4000 3061.998
##
## Residual Variance=0.9877
## Explained Variance=0.2343
## Total Variance=1.222
## R2=0.1917
#****
# Model 2: Estimation with latent.regression.em.normal
res2 <- sirt::latent.regression.em.normal( y=yast, sig.e=sig.e, X=X1)
## Regression Parameters
##
## est se.simple se t p beta fmi N.simple pseudoN.latent
## intercept 0.0112 0.0157 0.0180 0.6225 0.5336 0.0000 0.2345 4000 3062.041
## X 0.4275 0.0157 0.0180 23.7927 0.0000 0.3868 0.2350 4000 3062.041
## Z 0.2314 0.0156 0.0178 12.9870 0.0000 0.2111 0.2349 4000 3062.041
##
## Residual Variance=0.9877
## Explained Variance=0.2343
## Total Variance=1.222
## R2=0.1917
## -> Results between Model 1 and Model 2 are identical because they use
## the same input.
#***
# Model 3: Regression model based on true scores y
mod3 <- stats::lm( y ~ X + Z )
summary(mod3)
## Coefficients:
## Estimate Std. Error t value Pr(>|t|)
## (Intercept) 0.02364 0.01569 1.506 0.132
## X 0.42401 0.01570 27.016 <2e-16 ***
## Z 0.23804 0.01556 15.294 <2e-16 ***
## Residual standard error: 0.9925 on 3997 degrees of freedom
## Multiple R-squared: 0.1923, Adjusted R-squared: 0.1919
## F-statistic: 475.9 on 2 and 3997 DF, p-value: < 2.2e-16
#***
# Model 4: Regression model based on observed scores yast
mod4 <- stats::lm( yast ~ X + Z )
summary(mod4)
## Coefficients:
## Estimate Std. Error t value Pr(>|t|)
## (Intercept) 0.01101 0.01797 0.613 0.54
## X 0.42716 0.01797 23.764 <2e-16 ***
## Z 0.23174 0.01783 13.001 <2e-16 ***
## Residual standard error: 1.137 on 3997 degrees of freedom
## Multiple R-squared: 0.1535, Adjusted R-squared: 0.1531
## F-statistic: 362.4 on 2 and 3997 DF, p-value: < 2.2e-16
## End(Not run)
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