brm.sim: Functions for the Beta Item Response Model
In sirt: Supplementary Item Response Theory Models
brm-Methods R Documentation
Functions for the Beta Item Response Model
Description
Functions for simulating and estimating the Beta item response model
(Noel & Dauvier, 2007). brm.sim can be used for
simulating the model, brm.irf computes the item response
function. The Beta item response model is estimated as a discrete
version to enable estimation in standard IRT software like
mirt or TAM packages.
Usage
# simulating the beta item response model
brm.sim(theta, delta, tau, K=NULL)
# computing the item response function of the beta item response model
brm.irf( Theta, delta, tau, ncat, thdim=1, eps=1E-10 )
Arguments
theta
Ability vector of \theta values
delta
Vector of item difficulty parameters
tau
Vector item dispersion parameters
K
Number of discretized categories. The default is NULL which
means that the simulated item responses are real number values
between 0 and 1. If an integer K chosen, then values
are discretized such that values of 0, 1, ..., K-1 arise.
Theta
Matrix of the ability vector \bold{\theta}
ncat
Number of categories
thdim
Theta dimension in the matrix Theta on
which the item loads.
eps
Nuisance parameter which stabilize probabilities.
Details
The discrete version of the beta item response model is defined as follows.
Assume that for item i there are K categories resulting in
values k=0,1,\dots,K-1. Each value k is associated with a
corresponding the transformed value in [0,1], namely
q (k)=1/(2 \cdot K), 1/(2 \cdot K) + 1/K, \ldots, 1 - 1/(2 \cdot K) .
The item response model is defined as
P( X_{pi}=x_{pi} | \theta_p) \propto
q( x_{pi} )^{ m_{pi} - 1 } [ 1- q( x_{pi} ) ]^{ n_{pi} - 1 }
This density is a discrete version of a Beta distribution with
shape parameters m_{pi} and n_{pi}. These parameters are
defined as
m_{pi}=\mathrm{exp} \left[ ( \theta_p - \delta_i + \tau_i ) / 2 \right]
\qquad \mbox{and} \qquad
n_{pi}=\mathrm{exp} \left[ ( - \theta_p + \delta_i + \tau_i ) / 2 \right]
The item response function can also be formulated as
\mathrm{log} \left[ P( X_{pi}=x_{pi} | \theta_p) \right] \propto
( m_{pi} - 1 ) \cdot \mathrm{log} [ q( x_{pi} ) ] +
( n_{pi} - 1 ) \cdot \mathrm{log} [ 1- q( x_{pi} ) ]
The item parameters can be reparameterized as
a_{i}=\mathrm{exp} \left[ ( - \delta_i + \tau_i ) / 2 \right] and
b_{i}=\mathrm{exp} \left[ ( \delta_i + \tau_i ) / 2 \right].
Then, the original item parameters can be retrieved by
\tau_i=\mathrm{log} ( a_i b_i) and
\delta_i=\mathrm{log} ( b_i / a_i).
Using \gamma _p=\mathrm{exp} ( \theta_p / 2) , we obtain
\mathrm{log} \left[ P( X_{pi}=x_{pi} | \theta_p) \right] \propto
a_{i} \gamma_p \cdot \mathrm{log} [ q( x_{pi} ) ] +
b_i / \gamma_p \cdot \mathrm{log} [ 1- q( x_{pi} ) ] -
\left[ \mathrm{log} q( x_{pi} ) + \mathrm{log} [ 1- q( x_{pi} ) ] \right]
This formulation enables the specification of the Beta item response
model as a structured latent class model
(see TAM::tam.mml.3pl;
Example 1).
See Smithson and Verkuilen (2006) for motivations for treating
continuous indicators not as normally distributed variables.
Value
A simulated dataset of item responses if brm.sim is applied.
A matrix of item response probabilities if brm.irf is applied.
References
Gruen, B., Kosmidis, I., & Zeileis, A. (2012). Extended Beta regression
in R: Shaken, stirred, mixed, and partitioned.
Journal of Statistical Software, 48(11), 1-25.
\Sexpr[results=rd]{tools:::Rd_expr_doi("10.18637/jss.v048.i11")}
Noel, Y., & Dauvier, B. (2007). A beta item response model for continuous
bounded responses. Applied Psychological Measurement,
31(1), 47-73. \Sexpr[results=rd]{tools:::Rd_expr_doi("10.1177/0146621605287691")}
Smithson, M., & Verkuilen, J. (2006). A better lemon squeezer?
Maximum-likelihood regression with beta-distributed dependent variables.
Psychological Methods, 11(1), 54-71.
doi: 10.1037/1082-989X.11.1.54
See Also
See also the betareg package for fitting Beta regression
regression models in R (Gruen, Kosmidis & Zeileis, 2012).
Examples
#############################################################################
# EXAMPLE 1: Simulated data beta response model
#############################################################################
#*** (1) Simulation of the beta response model
# Table 3 (p. 65) of Noel and Dauvier (2007)
delta <- c( -.942, -.649, -.603, -.398, -.379, .523, .649, .781, .907 )
tau <- c( .382, .166, 1.799, .615, 2.092, 1.988, 1.899, 1.439, 1.057 )
K <- 5 # number of categories for discretization
N <- 500 # number of persons
I <- length(delta) # number of items
set.seed(865)
theta <- stats::rnorm( N )
dat <- sirt::brm.sim( theta=theta, delta=delta, tau=tau, K=K)
psych::describe(dat)
#*** (2) some preliminaries for estimation of the model in mirt
#*** define a mirt function
library(mirt)
Theta <- matrix( seq( -4, 4, len=21), ncol=1 )
# compute item response function
ii <- 1 # item ii=1
b1 <- sirt::brm.irf( Theta=Theta, delta=delta[ii], tau=tau[ii], ncat=K )
# plot item response functions
graphics::matplot( Theta[,1], b1, type="l" )
#*** defining the beta item response function for estimation in mirt
par <- c( 0, 1, 1)
names(par) <- c( "delta", "tau","thdim")
est <- c( TRUE, TRUE, FALSE )
names(est) <- names(par)
brm.icc <- function( par, Theta, ncat ){
delta <- par[1]
tau <- par[2]
thdim <- par[3]
probs <- sirt::brm.irf( Theta=Theta, delta=delta, tau=tau, ncat=ncat,
thdim=thdim)
return(probs)
}
name <- "brm"
# create item response function
brm.itemfct <- mirt::createItem(name, par=par, est=est, P=brm.icc)
#*** define model in mirt
mirtmodel <- mirt::mirt.model("
F1=1-9
" )
itemtype <- rep("brm", I )
customItems <- list("brm"=brm.itemfct)
# define parameters to be estimated
mod1.pars <- mirt::mirt(dat, mirtmodel, itemtype=itemtype,
customItems=customItems, pars="values")
## Not run:
#*** (3) estimate beta item response model in mirt
mod1 <- mirt::mirt(dat,mirtmodel, itemtype=itemtype, customItems=customItems,
pars=mod1.pars, verbose=TRUE )
# model summaries
print(mod1)
summary(mod1)
coef(mod1)
# estimated coefficients and comparison with simulated data
cbind( sirt::mirt.wrapper.coef( mod1 )$coef, delta, tau )
mirt.wrapper.itemplot(mod1,ask=TRUE)
#---------------------------
# estimate beta item response model in TAM
library(TAM)
# define the skill space: standard normal distribution
TP <- 21 # number of theta points
theta.k <- diag(TP)
theta.vec <- seq( -6,6, len=TP)
d1 <- stats::dnorm(theta.vec)
d1 <- d1 / sum(d1)
delta.designmatrix <- matrix( log(d1), ncol=1 )
delta.fixed <- cbind( 1, 1, 1 )
# define design matrix E
E <- array(0, dim=c(I,K,TP,2*I + 1) )
dimnames(E)[[1]] <- items <- colnames(dat)
dimnames(E)[[4]] <- c( paste0( rep( items, each=2 ),
rep( c("_a","_b" ), I) ), "one" )
for (ii in 1:I){
for (kk in 1:K){
for (tt in 1:TP){
qk <- (2*(kk-1)+1)/(2*K)
gammap <- exp( theta.vec[tt] / 2 )
E[ii, kk, tt, 2*(ii-1) + 1 ] <- gammap * log( qk )
E[ii, kk, tt, 2*(ii-1) + 2 ] <- 1 / gammap * log( 1 - qk )
E[ii, kk, tt, 2*I+1 ] <- - log(qk) - log( 1 - qk )
}
}
}
gammaslope.fixed <- cbind( 2*I+1, 1 )
gammaslope <- exp( rep(0,2*I+1) )
# estimate model in TAM
mod2 <- TAM::tam.mml.3pl(resp=dat, E=E,control=list(maxiter=100),
skillspace="discrete", delta.designmatrix=delta.designmatrix,
delta.fixed=delta.fixed, theta.k=theta.k, gammaslope=gammaslope,
gammaslope.fixed=gammaslope.fixed, notA=TRUE )
summary(mod2)
# extract original tau and delta parameters
m1 <- matrix( mod2$gammaslope[1:(2*I) ], ncol=2, byrow=TRUE )
m1 <- as.data.frame(m1)
colnames(m1) <- c("a","b")
m1$delta.TAM <- log( m1$b / m1$a)
m1$tau.TAM <- log( m1$a * m1$b )
# compare estimated parameter
m2 <- cbind( sirt::mirt.wrapper.coef( mod1 )$coef, delta, tau )[,-1]
colnames(m2) <- c( "delta.mirt", "tau.mirt", "thdim","delta.true","tau.true" )
m2 <- cbind(m1,m2)
round( m2, 3 )
## End(Not run)
sirt documentation built on May 29, 2024, 8:43 a.m.
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| brm-Methods | R Documentation |
Functions for the Beta Item Response Model
Description
Functions for simulating and estimating the Beta item response model
(Noel & Dauvier, 2007). brm.sim can be used for
simulating the model, brm.irf computes the item response
function. The Beta item response model is estimated as a discrete
version to enable estimation in standard IRT software like
mirt or TAM packages.
Usage
# simulating the beta item response model
brm.sim(theta, delta, tau, K=NULL)
# computing the item response function of the beta item response model
brm.irf( Theta, delta, tau, ncat, thdim=1, eps=1E-10 )
Arguments
theta |
Ability vector of |
delta |
Vector of item difficulty parameters |
tau |
Vector item dispersion parameters |
K |
Number of discretized categories. The default is |
Theta |
Matrix of the ability vector |
ncat |
Number of categories |
thdim |
Theta dimension in the matrix |
eps |
Nuisance parameter which stabilize probabilities. |
Details
The discrete version of the beta item response model is defined as follows.
Assume that for item i there are K categories resulting in
values k=0,1,\dots,K-1. Each value k is associated with a
corresponding the transformed value in [0,1], namely
q (k)=1/(2 \cdot K), 1/(2 \cdot K) + 1/K, \ldots, 1 - 1/(2 \cdot K) .
The item response model is defined as
P( X_{pi}=x_{pi} | \theta_p) \propto
q( x_{pi} )^{ m_{pi} - 1 } [ 1- q( x_{pi} ) ]^{ n_{pi} - 1 }
This density is a discrete version of a Beta distribution with
shape parameters m_{pi} and n_{pi}. These parameters are
defined as
m_{pi}=\mathrm{exp} \left[ ( \theta_p - \delta_i + \tau_i ) / 2 \right]
\qquad \mbox{and} \qquad
n_{pi}=\mathrm{exp} \left[ ( - \theta_p + \delta_i + \tau_i ) / 2 \right]
The item response function can also be formulated as
\mathrm{log} \left[ P( X_{pi}=x_{pi} | \theta_p) \right] \propto
( m_{pi} - 1 ) \cdot \mathrm{log} [ q( x_{pi} ) ] +
( n_{pi} - 1 ) \cdot \mathrm{log} [ 1- q( x_{pi} ) ]
The item parameters can be reparameterized as
a_{i}=\mathrm{exp} \left[ ( - \delta_i + \tau_i ) / 2 \right] and
b_{i}=\mathrm{exp} \left[ ( \delta_i + \tau_i ) / 2 \right].
Then, the original item parameters can be retrieved by
\tau_i=\mathrm{log} ( a_i b_i) and
\delta_i=\mathrm{log} ( b_i / a_i).
Using \gamma _p=\mathrm{exp} ( \theta_p / 2) , we obtain
\mathrm{log} \left[ P( X_{pi}=x_{pi} | \theta_p) \right] \propto
a_{i} \gamma_p \cdot \mathrm{log} [ q( x_{pi} ) ] +
b_i / \gamma_p \cdot \mathrm{log} [ 1- q( x_{pi} ) ] -
\left[ \mathrm{log} q( x_{pi} ) + \mathrm{log} [ 1- q( x_{pi} ) ] \right]
This formulation enables the specification of the Beta item response
model as a structured latent class model
(see TAM::tam.mml.3pl;
Example 1).
See Smithson and Verkuilen (2006) for motivations for treating continuous indicators not as normally distributed variables.
Value
A simulated dataset of item responses if brm.sim is applied.
A matrix of item response probabilities if brm.irf is applied.
References
Gruen, B., Kosmidis, I., & Zeileis, A. (2012). Extended Beta regression in R: Shaken, stirred, mixed, and partitioned. Journal of Statistical Software, 48(11), 1-25. \Sexpr[results=rd]{tools:::Rd_expr_doi("10.18637/jss.v048.i11")}
Noel, Y., & Dauvier, B. (2007). A beta item response model for continuous bounded responses. Applied Psychological Measurement, 31(1), 47-73. \Sexpr[results=rd]{tools:::Rd_expr_doi("10.1177/0146621605287691")}
Smithson, M., & Verkuilen, J. (2006). A better lemon squeezer? Maximum-likelihood regression with beta-distributed dependent variables. Psychological Methods, 11(1), 54-71. doi: 10.1037/1082-989X.11.1.54
See Also
See also the betareg package for fitting Beta regression regression models in R (Gruen, Kosmidis & Zeileis, 2012).
Examples
#############################################################################
# EXAMPLE 1: Simulated data beta response model
#############################################################################
#*** (1) Simulation of the beta response model
# Table 3 (p. 65) of Noel and Dauvier (2007)
delta <- c( -.942, -.649, -.603, -.398, -.379, .523, .649, .781, .907 )
tau <- c( .382, .166, 1.799, .615, 2.092, 1.988, 1.899, 1.439, 1.057 )
K <- 5 # number of categories for discretization
N <- 500 # number of persons
I <- length(delta) # number of items
set.seed(865)
theta <- stats::rnorm( N )
dat <- sirt::brm.sim( theta=theta, delta=delta, tau=tau, K=K)
psych::describe(dat)
#*** (2) some preliminaries for estimation of the model in mirt
#*** define a mirt function
library(mirt)
Theta <- matrix( seq( -4, 4, len=21), ncol=1 )
# compute item response function
ii <- 1 # item ii=1
b1 <- sirt::brm.irf( Theta=Theta, delta=delta[ii], tau=tau[ii], ncat=K )
# plot item response functions
graphics::matplot( Theta[,1], b1, type="l" )
#*** defining the beta item response function for estimation in mirt
par <- c( 0, 1, 1)
names(par) <- c( "delta", "tau","thdim")
est <- c( TRUE, TRUE, FALSE )
names(est) <- names(par)
brm.icc <- function( par, Theta, ncat ){
delta <- par[1]
tau <- par[2]
thdim <- par[3]
probs <- sirt::brm.irf( Theta=Theta, delta=delta, tau=tau, ncat=ncat,
thdim=thdim)
return(probs)
}
name <- "brm"
# create item response function
brm.itemfct <- mirt::createItem(name, par=par, est=est, P=brm.icc)
#*** define model in mirt
mirtmodel <- mirt::mirt.model("
F1=1-9
" )
itemtype <- rep("brm", I )
customItems <- list("brm"=brm.itemfct)
# define parameters to be estimated
mod1.pars <- mirt::mirt(dat, mirtmodel, itemtype=itemtype,
customItems=customItems, pars="values")
## Not run:
#*** (3) estimate beta item response model in mirt
mod1 <- mirt::mirt(dat,mirtmodel, itemtype=itemtype, customItems=customItems,
pars=mod1.pars, verbose=TRUE )
# model summaries
print(mod1)
summary(mod1)
coef(mod1)
# estimated coefficients and comparison with simulated data
cbind( sirt::mirt.wrapper.coef( mod1 )$coef, delta, tau )
mirt.wrapper.itemplot(mod1,ask=TRUE)
#---------------------------
# estimate beta item response model in TAM
library(TAM)
# define the skill space: standard normal distribution
TP <- 21 # number of theta points
theta.k <- diag(TP)
theta.vec <- seq( -6,6, len=TP)
d1 <- stats::dnorm(theta.vec)
d1 <- d1 / sum(d1)
delta.designmatrix <- matrix( log(d1), ncol=1 )
delta.fixed <- cbind( 1, 1, 1 )
# define design matrix E
E <- array(0, dim=c(I,K,TP,2*I + 1) )
dimnames(E)[[1]] <- items <- colnames(dat)
dimnames(E)[[4]] <- c( paste0( rep( items, each=2 ),
rep( c("_a","_b" ), I) ), "one" )
for (ii in 1:I){
for (kk in 1:K){
for (tt in 1:TP){
qk <- (2*(kk-1)+1)/(2*K)
gammap <- exp( theta.vec[tt] / 2 )
E[ii, kk, tt, 2*(ii-1) + 1 ] <- gammap * log( qk )
E[ii, kk, tt, 2*(ii-1) + 2 ] <- 1 / gammap * log( 1 - qk )
E[ii, kk, tt, 2*I+1 ] <- - log(qk) - log( 1 - qk )
}
}
}
gammaslope.fixed <- cbind( 2*I+1, 1 )
gammaslope <- exp( rep(0,2*I+1) )
# estimate model in TAM
mod2 <- TAM::tam.mml.3pl(resp=dat, E=E,control=list(maxiter=100),
skillspace="discrete", delta.designmatrix=delta.designmatrix,
delta.fixed=delta.fixed, theta.k=theta.k, gammaslope=gammaslope,
gammaslope.fixed=gammaslope.fixed, notA=TRUE )
summary(mod2)
# extract original tau and delta parameters
m1 <- matrix( mod2$gammaslope[1:(2*I) ], ncol=2, byrow=TRUE )
m1 <- as.data.frame(m1)
colnames(m1) <- c("a","b")
m1$delta.TAM <- log( m1$b / m1$a)
m1$tau.TAM <- log( m1$a * m1$b )
# compare estimated parameter
m2 <- cbind( sirt::mirt.wrapper.coef( mod1 )$coef, delta, tau )[,-1]
colnames(m2) <- c( "delta.mirt", "tau.mirt", "thdim","delta.true","tau.true" )
m2 <- cbind(m1,m2)
round( m2, 3 )
## End(Not run)
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