lcmm: Estimation of mixed-effect models and latent class...
In CecileProust-Lima/lcmm: Extended Mixed Models Using Latent Classes and Latent Processes
lcmm R Documentation
Estimation of mixed-effect models and latent class mixed-effect models for
different types of outcomes (continuous Gaussian, continuous non-Gaussian or
ordinal)
Description
This function fits mixed models and latent class mixed models for different
types of outcomes. It handles continuous longitudinal outcomes (Gaussian or
non-Gaussian) as well as bounded quantitative, discrete and ordinal
longitudinal outcomes. The different types of outcomes are taken into
account using parameterized nonlinear link functions between the observed
outcome and the underlying latent process of interest it measures. At the
latent process level, the model estimates a standard linear mixed model or a
latent class linear mixed model when heterogeneity in the population is
investigated (in the same way as in function hlme). It should be
noted that the program also works when no random-effect is included.
Parameters of the nonlinear link function and of the latent process mixed
model are estimated simultaneously using a maximum likelihood method.
Usage
lcmm(
fixed,
mixture,
random,
subject,
classmb,
ng = 1,
idiag = FALSE,
nwg = FALSE,
link = "linear",
intnodes = NULL,
epsY = 0.5,
cor = NULL,
data,
B,
convB = 1e-04,
convL = 1e-04,
convG = 1e-04,
maxiter = 100,
nsim = 100,
prior,
pprior = NULL,
range = NULL,
subset = NULL,
na.action = 1,
posfix = NULL,
partialH = FALSE,
verbose = FALSE,
returndata = FALSE,
var.time = NULL,
nproc = 1,
clustertype = NULL,
computeDiscrete = NULL
)
Arguments
fixed
a two-sided linear formula object for specifying the
fixed-effects in the linear mixed model at the latent process level. The
response outcome is on the left of ~ and the covariates are separated
by + on the right of the ~. Fo identifiability purposes, the
intercept specified by default should not be removed by a -1.
mixture
a one-sided formula object for the class-specific fixed
effects in the latent process mixed model (to specify only for a number of
latent classes greater than 1). Among the list of covariates included in
fixed, the covariates with class-specific regression parameters are
entered in mixture separated by +. By default, an intercept
is included. If no intercept, -1 should be the first term included.
random
an optional one-sided formula for the random-effects in the
latent process mixed model. Covariates with a random-effect are separated by
+. By default, no random effect is included.
subject
name of the covariate representing the grouping structure.
classmb
an optional one-sided formula describing the covariates in
the class-membership multinomial logistic model. Covariates included are
separated by +. No intercept should be included in this formula.
ng
number of latent classes considered. If ng=1 no
mixture nor classmb should be specified. If ng>1,
mixture is required.
idiag
optional logical for the variance-covariance structure of the
random-effects. If FALSE, a non structured matrix of
variance-covariance is considered (by default). If TRUE a diagonal
matrix of variance-covariance is considered.
nwg
optional logical of class-specific variance-covariance of the
random-effects. If FALSE the variance-covariance matrix is common
over latent classes (by default). If TRUE a class-specific
proportional parameter multiplies the variance-covariance matrix in each
class (the proportional parameter in the last latent class equals 1 to
ensure identifiability).
link
optional family of link functions to estimate. By default,
"linear" option specifies a linear link function leading to a standard
linear mixed model (homogeneous or heterogeneous as estimated in
hlme). Other possibilities include "beta" for estimating a link
function from the family of Beta cumulative distribution functions,
"thresholds" for using a threshold model to describe the correspondence
between each level of an ordinal outcome and the underlying latent process,
and "Splines" for approximating the link function by I-splines. For this
latter case, the number of nodes and the nodes location should be also
specified. The number of nodes is first entered followed by -, then
the location is specified with "equi", "quant" or "manual" for respectively
equidistant nodes, nodes at quantiles of the marker distribution or interior
nodes entered manually in argument intnodes. It is followed by
- and finally "splines" is indicated. For example, "7-equi-splines"
means I-splines with 7 equidistant nodes, "6-quant-splines" means I-splines
with 6 nodes located at the quantiles of the marker distribution and
"9-manual-splines" means I-splines with 9 nodes, the vector of 7 interior
nodes being entered in the argument intnodes.
intnodes
optional vector of interior nodes. This argument is only
required for a I-splines link function with nodes entered manually.
epsY
optional definite positive real used to rescale the marker in
(0,1) when the beta link function is used. By default, epsY=0.5.
cor
optional brownian motion or autoregressive process modeling the
correlation between the observations. "BM" or "AR" should be specified,
followed by the time variable between brackets. By default, no correlation
is added.
data
optional data frame containing the variables named in
fixed, mixture, random, classmb and
subject.
B
optional specification for the initial values for the parameters.
Three options are allowed: (1) a vector of initial values is entered (the
order in which the parameters are included is detailed in details
section). (2) nothing is specified. A preliminary analysis involving the
estimation of a standard linear mixed model is performed to choose initial
values. (3) when ng>1, a lcmm object is entered. It should correspond to
the exact same structure of model but with ng=1. The program will
automatically generate initial values from this model. This specification
avoids the preliminary analysis indicated in (2). Note that due to possible
local maxima, the B vector should be specified and several different
starting points should be tried.
convB
optional threshold for the convergence criterion based on the
parameter stability. By default, convB=0.0001.
convL
optional threshold for the convergence criterion based on the
log-likelihood stability. By default, convL=0.0001.
convG
optional threshold for the convergence criterion based on the
derivatives. By default, convG=0.0001.
maxiter
optional maximum number of iterations for the Marquardt
iterative algorithm. By default, maxiter=100.
nsim
number of points used to plot the estimated link function. By
default, nsim=100.
prior
name of the covariate containing the prior on the latent class
membership. The covariate should be an integer with values in 0,1,...,ng.
When there is no prior, the value should be 0. When there is a prior for the
subject, the value should be the number of the latent class (in 1,...,ng).
pprior
optional vector specifying the names of the covariates containing the
prior probabilities to belong to each latent class. These probabilities should be
between 0 and 1 and should sum up to 1 for each subject.
range
optional vector indicating the range of the outcome (that is
the minimum and maximum). By default, the range is defined according to the
minimum and maximum observed values of the outcome. The option should be
used only for Beta and Splines transformations.
subset
optional vector giving the subset of observations in
data to use. By default, all lines.
na.action
Integer indicating how NAs are managed. The default is 1
for 'na.omit'. The alternative is 2 for 'na.fail'. Other options such as
'na.pass' or 'na.exclude' are not implemented in the current version.
posfix
Optional vector specifying the indices in vector B of the
parameters that should not be estimated. Default to NULL, all parameters are
estimated.
partialH
optional logical for Splines link functions only.
Indicates whether the parameters of the link functions can be dropped from
the Hessian matrix to define convergence criteria.
verbose
logical indicating if information about computation should be
reported. Default to TRUE.
returndata
logical indicating if data used for computation should be
returned. Default to FALSE, data are not returned.
var.time
optional character indicating the name of the time variable.
nproc
the number cores for parallel computation.
Default to 1 (sequential mode).
clustertype
optional character indicating the type of cluster for parallel computation.
computeDiscrete
optional logical indicating if a dscrete likelihood and UACV
should be computed. By default, if the outcome only consists of integers computeDiscrete=TRUE.
Details
A. THE PARAMETERIZED LINK FUNCTIONS
lcmm function estimates mixed models and latent class mixed models
for different types of outcomes by assuming a parameterized link function
for linking the outcome Y(t) with the underlying latent process L(t) it
measures. To fix the latent process dimension, we chose to constrain the
(first) intercept of the latent class mixed model at the latent process
level at 0 and the standard error of the gaussian error of measurement at 1.
These two parameters are replaced by additional parameters in the
parameterized link function :
1. With the "linear" link function, 2 parameters are required that
correspond directly to the intercept and the standard error: (Y - b1)/b2 =
L(t).
2. With the "beta" link function, 4 parameters are required for the
following transformation: [ h(Y(t)',b1,b2) - b3]/b4 where h is the Beta CDF
with canonical parameters c1 and c2 that can be derived from b1 and b2 as
c1=exp(b1)/[exp(b2)*(1+exp(b1))] and c2=1/[exp(b2)*(1+exp(b1))], and Y(t)'
is the rescaled outcome i.e. Y(t)'= [ Y(t) - min(Y(t)) + epsY ] / [
max(Y(t)) - min(Y(t)) +2*epsY ].
3. With the "splines" link function, n+2 parameters are required for the
following transformation b_1 + b_2*I_1(Y(t)) + ... + b_n+2 I_n+1(Y(t)),
where I_1,...,I_n+1 is the basis of quadratic I-splines. To constraint the
parameters to be positive, except for b_1, the program estimates b_k^* (for
k=2,...,n+2) so that b_k=(b_k^*)^2.
4. With the "thresholds" link function for an ordinal outcome in levels
0,...,C. A maximumn of C parameters are required for the following
transformation: Y(t)=c <=> b_c < L(t) <= b_c+1 with b_0 = - infinity and
b_C+1=+infinity. The number of parameters is reduced if some levels do not
have any information. For example, if a level c is not observed in the
dataset, the corresponding threshold b_c+1 is constrained to be the same
as the previous one b_c. The number of parameters in the link function is
reduced by 1.
To constraint the parameters to be increasing, except for the first
parameter b_1, the program estimates b_k^* (for k=2,...C) so that
b_k=b_k-1+(b_k^*)^2.
Details of these parameterized link functions can be found in the referred
papers.
B. THE VECTOR OF PARAMETERS B
The parameters in the vector of initial values B or in the vector of
maximum likelihood estimates best are included in the following
order: (1) ng-1 parameters are required for intercepts in the latent class
membership model, and if covariates are included in classmb, ng-1
paramaters should be entered for each one; (2) for all covariates in
fixed, one parameter is required if the covariate is not in
mixture, ng paramaters are required if the covariate is also in
mixture; When ng=1, the intercept is not estimated and no parameter
should be specified in B. When ng>1, the first intercept is not
estimated and only ng-1 parameters should be specified in B; (3) the
variance of each random-effect specified in random (including the
intercept) if idiag=TRUE and the inferior triangular
variance-covariance matrix of all the random-effects if idiag=FALSE;
(4) only if nwg=TRUE, ng-1 parameters for class-specific proportional
coefficients for the variance covariance matrix of the random-effects; (5)
In contrast with hlme, due to identifiability purposes, the standard error
of the Gaussian error is not estimated (fixed at 1), and should not be
specified in B; (6) The parameters of the link function: 2 for
"linear", 4 for "beta", n+2 for "splines" with n nodes and the number of
levels minus one for "thresholds".
C. CAUTIONS REGARDING THE USE OF THE PROGRAM
Some caution should be made when using the program. convergence criteria
are very strict as they are based on derivatives of the log-likelihood in
addition to the parameter and log-likelihood stability. In some cases, the
program may not converge and reach the maximum number of iterations fixed at
100. In this case, the user should check that parameter estimates at the
last iteration are not on the boundaries of the parameter space. If the
parameters are on the boundaries of the parameter space, the identifiability
of the model is critical. This may happen especially with splines parameters
that may be too close to 0 (lower boundary) or classmb parameters that are
too high or low (perfect classification). When identifiability of some
parameters is suspected, the program can be run again from the former
estimates by fixing the suspected parameters to their value with option
posfix. This usually solves the problem. An alternative is to remove the
parameters of the Beta of Splines link function from the inverse of the
Hessian with option partialH. If not, the program should be run again with
other initial values, with a higher maximum number of iterations or less
strict convergence tolerances.
Specifically when investigating heterogeneity (that is with ng>1): (1) As
the log-likelihood of a latent class model can have multiple maxima, a
careful choice of the initial values is crucial for ensuring convergence
toward the global maximum. The program can be run without entering the
vector of initial values (see point 2). However, we recommend to
systematically enter initial values in B and try different sets of
initial values. (2) The automatic choice of initial values we provide
requires the estimation of a preliminary linear mixed model. The user should
be aware that first, this preliminary analysis can take time for large
datatsets and second, that the generated initial values can be very not
likely and even may converge slowly to a local maximum. This is the reason
why several alternatives exist. The vector of initial values can be directly
specified in B the initial values can be generated (automatically or
randomly) from a model with ng=. Finally, function gridsearch
performs an automatic grid search.
D. NUMERICAL INTEGRATION WITH THE THRESHOLD LINK FUNCTION
With exception for the threshold link function, maximum likelihood
estimation implemented in lcmm does not require any numerical integration
over the random-effects so that the estimation procedure is relatively fast.
See Proust et al. (2006) for more details on the estimation procedure.
However, with the threshold link function and when at least one
random-effect is specified, a numerical integration over the random-effects
distribution is required in each computation of the individual contribution
to the likelihood which complicates greatly the estimation procedure. For
the moment, we do not allow any option regarding the numerical integration
technics used. 1. When a single random-effect is specified, we use a
standard non-adaptive Gaussian quadrature with 30 points. 2. When at least
two random-effects are specified, we use a multivariate non-adaptive
Gaussian quadrature implemented by Genz (1996) in HRMSYM Fortran subroutine.
Further developments should allow for adaptive technics and more options
regarding the numerical integration technic.
E. POSTERIOR DISCRETE LIKELIHOOD
Models involving nonlinear continuous link functions assume the continuous
data while the model with a threshold model assumes discrete data. As a
consequence, comparing likelihoods or criteria based on the likelihood (as
AIC) for these models is not possible as the former are based on a Lebesgue
measure and the latter on a counting measure. To make the comparison
possible, we compute the posterior discrete likelihood for all the models
with a nonlinear continuous link function. This posterior likelihood
considers the data as discrete; it is computed at the MLE (maximum
likelihood estimates) using the counting measure so that models with
threshold or continuous link functions become comparable. Further details
can be found in Proust-Lima, Amieva, Jacqmin-Gadda (2012).
In addition to the Akaike information criterion based on the discrete
posterior likelihood, we also compute a universal approximate
cross-validation criterion to compare models based on a different measure.
See Commenges, Proust-Lima, Samieri, Liquet (2015) for further details.
Value
The list returned is:
ns
number of grouping units in the
dataset
ng
number of latent classes
loglik
log-likelihood of
the model
best
vector of parameter estimates in the same order as
specified in B and detailed in section details
V
if the model converged (conv=1 or 3), vector containing the upper triangle
matrix of variance-covariance estimates of Best with exception for
variance-covariance parameters of the random-effects for which V contains the
variance-covariance estimates of the Cholesky transformed parameters displayed in
cholesky. If conv=2, V contains the second derivatives of the
log-likelihood.
gconv
vector of convergence criteria: 1. on the
parameters, 2. on the likelihood, 3. on the derivatives
conv
status
of convergence: =1 if the convergence criteria were satisfied, =2 if the
maximum number of iterations was reached, =4 or 5 if a problem occured
during optimisation
call
the matched call
niter
number of
Marquardt iterations
dataset
dataset
N
internal information
used in related functions
idiag
internal information used in related
functions
pred
table of individual predictions and residuals in the
underlying latent process scale; it includes marginal predictions (pred_m),
marginal residuals (resid_m), subject-specific predictions (pred_ss) and
subject-specific residuals (resid_ss) averaged over classes, the transformed
observations in the latent process scale (obs) and finally the
class-specific marginal and subject-specific predictions (with the number of
the latent class: pred_m_1,pred_m_2,...,pred_ss_1,pred_ss_2,...). If var.time
is specified, the corresponding measurement time is also included. This
output is not available yet when specifying a thresholds transformation.
pprob
table of posterior classification and posterior individual
class-membership probabilities
Xnames
list of covariates included in
the model
predRE
table containing individual predictions of the
random-effects : a column per random-effect, a line per subject. This output
is not available yet when specifying a thresholds transformation.
cholesky
vector containing the estimates of the Cholesky transformed
parameters of the variance-covariance matrix of the random-effects
estimlink
table containing the simulated values of the marker and
corresponding estimated link function
epsY
definite positive real
used to rescale the marker in (0,1) when the beta link function is used. By
default, epsY=0.5.
linktype
indicator of link function type: 0 for
linear, 1 for beta, 2 for splines and 3 for thresholds
linknodes
vector of nodes useful only for the 'splines' link
function
data
the original data set (if returndata is TRUE)
Author(s)
Cecile Proust-Lima, Amadou Diakite, Benoit Liquet and Viviane
Philipps
References
Proust-Lima C, Philipps V, Liquet B (2017). Estimation of Extended Mixed
Models Using Latent Classes and Latent Processes: The R Package lcmm.
Journal of Statistical Software, 78(2), 1-56. doi:10.18637/jss.v078.i02
Genz and Keister (1996). Fully symmetric interpolatory rules for multiple
integrals over infinite regions with gaussian weight. Journal of
Computational and Applied Mathematics 71: 299-309.
Proust and Jacqmin-Gadda (2005). Estimation of linear mixed models with a
mixture of distribution for the random-effects. Comput Methods Programs
Biomed 78: 165-73.
Proust, Jacqmin-Gadda, Taylor, Ganiayre, and Commenges (2006). A nonlinear
model with latent process for cognitive evolution using multivariate
longitudinal data. Biometrics 62: 1014-24.
Proust-Lima, Dartigues and Jacqmin-Gadda (2011). Misuse of the linear mixed
model when evaluating risk factors of cognitive decline. Amer J Epidemiol
174(9): 1077-88.
Proust-Lima, Amieva and Jacqmin-Gadda (2013). Analysis of multivariate mixed
longitudinal data : a flexible latent process approach, British Journal of
Mathematical and Statistical Psychology 66(3): 470-87.
Commenges, Proust-Lima, Samieri, Liquet (2015). A universal approximate
cross-validation criterion for regular risk functions. Int J Biostat. 2015
May;11(1):51-67
See Also
postprob, plot.lcmm, plot.predict,
hlme
Examples
## Not run:
#### Estimation of homogeneous mixed models with different assumed link
#### functions, a quadratic mean trajectory for the latent process and
#### correlated random intercept and slope (the random quadratic slope
#### was removed as it did not improve the fit of the data).
#### -- comparison of linear, Beta and 3 different splines link functions --
# linear link function
m10<-lcmm(Ydep2~Time+I(Time^2),random=~Time,subject='ID',ng=1,
data=data_lcmm,link="linear")
summary(m10)
# Beta link function
m11<-lcmm(Ydep2~Time+I(Time^2),random=~Time,subject='ID',ng=1,
data=data_lcmm,link="beta")
summary(m11)
plot(m11,which="linkfunction",bty="l")
# I-splines with 3 equidistant nodes
m12<-lcmm(Ydep2~Time+I(Time^2),random=~Time,subject='ID',ng=1,
data=data_lcmm,link="3-equi-splines")
summary(m12)
# I-splines with 5 nodes at quantiles
m13<-lcmm(Ydep2~Time+I(Time^2),random=~Time,subject='ID',ng=1,
data=data_lcmm,link="5-quant-splines")
summary(m13)
# I-splines with 5 nodes, and interior nodes entered manually
m14<-lcmm(Ydep2~Time+I(Time^2),random=~Time,subject='ID',ng=1,
data=data_lcmm,link="5-manual-splines",intnodes=c(10,20,25))
summary(m14)
plot(m14,which="linkfunction",bty="l")
# Thresholds
# Especially for the threshold link function, we recommend to estimate
# models with increasing complexity and use estimates of previous ones
# to specify plausible initial values (we remind that estimation of
# models with threshold link function involves a computationally demanding
# numerical integration -here of size 3)
m15<-lcmm(Ydep2~Time+I(Time^2),random=~Time,subject='ID',ng=1
,data=data_lcmm,link="thresholds",maxiter=100,
B=c(-0.8379, -0.1103, 0.3832, 0.3788 , 0.4524, -7.3180, 0.5917, 0.7364,
0.6530, 0.4038, 0.4290, 0.6099, 0.6014 , 0.5354 , 0.5029 , 0.5463,
0.5310 , 0.5352, 0.6498, 0.6653, 0.5851, 0.6525, 0.6701 , 0.6670 ,
0.6767 , 0.7394 , 0.7426, 0.7153, 0.7702, 0.6421))
summary(m15)
plot(m15,which="linkfunction",bty="l")
#### Plot of estimated different link functions:
#### (applicable for models that only differ in the "link function" used.
#### Otherwise, the latent process scale is different and a rescaling
#### is necessary)
plot(m10,which="linkfunction",col=1,xlab="latent process",ylab="marker",
bty="l",xlim=c(-10,5),legend=NULL)
plot(m11,which="linkfunction",add=TRUE,col=2,legend=NULL)
plot(m12,which="linkfunction",add=TRUE,col=3,legend=NULL)
plot(m13,which="linkfunction",add=TRUE,col=4,legend=NULL)
plot(m14,which="linkfunction",add=TRUE,col=5,legend=NULL)
plot(m15,which="linkfunction",add=TRUE,col=6,legend=NULL)
legend(x="bottomright",legend=c("linear","beta","spl_3e","spl_5q","spl_5m","thresholds"),
col=1:6,lty=1,inset=.02,box.lty=0)
#### Estimation of 2-latent class mixed models with different assumed link
#### functions with individual and class specific linear trend
#### for illustration, only default initial values where used but other
#### sets of initial values should also be tried to ensure convergence
#### towards the golbal maximum
# Linear link function
m20<-lcmm(Ydep2~Time,random=~Time,subject='ID',mixture=~Time,ng=2,
idiag=TRUE,data=data_lcmm,link="linear",B=c(-0.98,0.79,-2.09,
-0.81,0.19,0.55,24.49,2.24))
summary(m20)
postprob(m20)
# Beta link function
m21<-lcmm(Ydep2~Time,random=~Time,subject='ID',mixture=~Time,ng=2,
idiag=TRUE,data=data_lcmm,link="beta",B=c(-0.1,-0.56,-0.4,-1.77,
0.53,0.14,0.6,-0.83,0.73,0.09))
summary(m21)
postprob(m21)
# I-splines link function (and 5 nodes at quantiles)
m22<-lcmm(Ydep2~Time,random=~Time,subject='ID',mixture=~Time,ng=2,
idiag=TRUE,data=data_lcmm,link="5-quant-splines",B=c(0.12,0.63,
-1.76,-0.39,0.51,0.13,-7.37,1.05,1.28,1.96,1.3,0.93,1.05))
summary(m22)
postprob(m22)
data <- data_lcmm[data_lcmm$ID==193,]
plot(predictL(m22,var.time="Time",newdata=data,bty="l")
## End(Not run)
CecileProust-Lima/lcmm documentation built on March 3, 2024, 5:23 p.m.
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| lcmm | R Documentation |
Estimation of mixed-effect models and latent class mixed-effect models for different types of outcomes (continuous Gaussian, continuous non-Gaussian or ordinal)
Description
This function fits mixed models and latent class mixed models for different
types of outcomes. It handles continuous longitudinal outcomes (Gaussian or
non-Gaussian) as well as bounded quantitative, discrete and ordinal
longitudinal outcomes. The different types of outcomes are taken into
account using parameterized nonlinear link functions between the observed
outcome and the underlying latent process of interest it measures. At the
latent process level, the model estimates a standard linear mixed model or a
latent class linear mixed model when heterogeneity in the population is
investigated (in the same way as in function hlme). It should be
noted that the program also works when no random-effect is included.
Parameters of the nonlinear link function and of the latent process mixed
model are estimated simultaneously using a maximum likelihood method.
Usage
lcmm(
fixed,
mixture,
random,
subject,
classmb,
ng = 1,
idiag = FALSE,
nwg = FALSE,
link = "linear",
intnodes = NULL,
epsY = 0.5,
cor = NULL,
data,
B,
convB = 1e-04,
convL = 1e-04,
convG = 1e-04,
maxiter = 100,
nsim = 100,
prior,
pprior = NULL,
range = NULL,
subset = NULL,
na.action = 1,
posfix = NULL,
partialH = FALSE,
verbose = FALSE,
returndata = FALSE,
var.time = NULL,
nproc = 1,
clustertype = NULL,
computeDiscrete = NULL
)
Arguments
fixed |
a two-sided linear formula object for specifying the
fixed-effects in the linear mixed model at the latent process level. The
response outcome is on the left of |
mixture |
a one-sided formula object for the class-specific fixed
effects in the latent process mixed model (to specify only for a number of
latent classes greater than 1). Among the list of covariates included in
|
random |
an optional one-sided formula for the random-effects in the
latent process mixed model. Covariates with a random-effect are separated by
|
subject |
name of the covariate representing the grouping structure. |
classmb |
an optional one-sided formula describing the covariates in
the class-membership multinomial logistic model. Covariates included are
separated by |
ng |
number of latent classes considered. If |
idiag |
optional logical for the variance-covariance structure of the
random-effects. If |
nwg |
optional logical of class-specific variance-covariance of the
random-effects. If |
link |
optional family of link functions to estimate. By default,
"linear" option specifies a linear link function leading to a standard
linear mixed model (homogeneous or heterogeneous as estimated in
|
intnodes |
optional vector of interior nodes. This argument is only required for a I-splines link function with nodes entered manually. |
epsY |
optional definite positive real used to rescale the marker in (0,1) when the beta link function is used. By default, epsY=0.5. |
cor |
optional brownian motion or autoregressive process modeling the correlation between the observations. "BM" or "AR" should be specified, followed by the time variable between brackets. By default, no correlation is added. |
data |
optional data frame containing the variables named in
|
B |
optional specification for the initial values for the parameters.
Three options are allowed: (1) a vector of initial values is entered (the
order in which the parameters are included is detailed in |
convB |
optional threshold for the convergence criterion based on the parameter stability. By default, convB=0.0001. |
convL |
optional threshold for the convergence criterion based on the log-likelihood stability. By default, convL=0.0001. |
convG |
optional threshold for the convergence criterion based on the derivatives. By default, convG=0.0001. |
maxiter |
optional maximum number of iterations for the Marquardt iterative algorithm. By default, maxiter=100. |
nsim |
number of points used to plot the estimated link function. By default, nsim=100. |
prior |
name of the covariate containing the prior on the latent class membership. The covariate should be an integer with values in 0,1,...,ng. When there is no prior, the value should be 0. When there is a prior for the subject, the value should be the number of the latent class (in 1,...,ng). |
pprior |
optional vector specifying the names of the covariates containing the prior probabilities to belong to each latent class. These probabilities should be between 0 and 1 and should sum up to 1 for each subject. |
range |
optional vector indicating the range of the outcome (that is the minimum and maximum). By default, the range is defined according to the minimum and maximum observed values of the outcome. The option should be used only for Beta and Splines transformations. |
subset |
optional vector giving the subset of observations in
|
na.action |
Integer indicating how NAs are managed. The default is 1 for 'na.omit'. The alternative is 2 for 'na.fail'. Other options such as 'na.pass' or 'na.exclude' are not implemented in the current version. |
posfix |
Optional vector specifying the indices in vector B of the parameters that should not be estimated. Default to NULL, all parameters are estimated. |
partialH |
optional logical for Splines link functions only. Indicates whether the parameters of the link functions can be dropped from the Hessian matrix to define convergence criteria. |
verbose |
logical indicating if information about computation should be reported. Default to TRUE. |
returndata |
logical indicating if data used for computation should be returned. Default to FALSE, data are not returned. |
var.time |
optional character indicating the name of the time variable. |
nproc |
the number cores for parallel computation. Default to 1 (sequential mode). |
clustertype |
optional character indicating the type of cluster for parallel computation. |
computeDiscrete |
optional logical indicating if a dscrete likelihood and UACV should be computed. By default, if the outcome only consists of integers computeDiscrete=TRUE. |
Details
A. THE PARAMETERIZED LINK FUNCTIONS
lcmm function estimates mixed models and latent class mixed models
for different types of outcomes by assuming a parameterized link function
for linking the outcome Y(t) with the underlying latent process L(t) it
measures. To fix the latent process dimension, we chose to constrain the
(first) intercept of the latent class mixed model at the latent process
level at 0 and the standard error of the gaussian error of measurement at 1.
These two parameters are replaced by additional parameters in the
parameterized link function :
1. With the "linear" link function, 2 parameters are required that correspond directly to the intercept and the standard error: (Y - b1)/b2 = L(t).
2. With the "beta" link function, 4 parameters are required for the following transformation: [ h(Y(t)',b1,b2) - b3]/b4 where h is the Beta CDF with canonical parameters c1 and c2 that can be derived from b1 and b2 as c1=exp(b1)/[exp(b2)*(1+exp(b1))] and c2=1/[exp(b2)*(1+exp(b1))], and Y(t)' is the rescaled outcome i.e. Y(t)'= [ Y(t) - min(Y(t)) + epsY ] / [ max(Y(t)) - min(Y(t)) +2*epsY ].
3. With the "splines" link function, n+2 parameters are required for the following transformation b_1 + b_2*I_1(Y(t)) + ... + b_n+2 I_n+1(Y(t)), where I_1,...,I_n+1 is the basis of quadratic I-splines. To constraint the parameters to be positive, except for b_1, the program estimates b_k^* (for k=2,...,n+2) so that b_k=(b_k^*)^2.
4. With the "thresholds" link function for an ordinal outcome in levels 0,...,C. A maximumn of C parameters are required for the following transformation: Y(t)=c <=> b_c < L(t) <= b_c+1 with b_0 = - infinity and b_C+1=+infinity. The number of parameters is reduced if some levels do not have any information. For example, if a level c is not observed in the dataset, the corresponding threshold b_c+1 is constrained to be the same as the previous one b_c. The number of parameters in the link function is reduced by 1.
To constraint the parameters to be increasing, except for the first parameter b_1, the program estimates b_k^* (for k=2,...C) so that b_k=b_k-1+(b_k^*)^2.
Details of these parameterized link functions can be found in the referred papers.
B. THE VECTOR OF PARAMETERS B
The parameters in the vector of initial values B or in the vector of
maximum likelihood estimates best are included in the following
order: (1) ng-1 parameters are required for intercepts in the latent class
membership model, and if covariates are included in classmb, ng-1
paramaters should be entered for each one; (2) for all covariates in
fixed, one parameter is required if the covariate is not in
mixture, ng paramaters are required if the covariate is also in
mixture; When ng=1, the intercept is not estimated and no parameter
should be specified in B. When ng>1, the first intercept is not
estimated and only ng-1 parameters should be specified in B; (3) the
variance of each random-effect specified in random (including the
intercept) if idiag=TRUE and the inferior triangular
variance-covariance matrix of all the random-effects if idiag=FALSE;
(4) only if nwg=TRUE, ng-1 parameters for class-specific proportional
coefficients for the variance covariance matrix of the random-effects; (5)
In contrast with hlme, due to identifiability purposes, the standard error
of the Gaussian error is not estimated (fixed at 1), and should not be
specified in B; (6) The parameters of the link function: 2 for
"linear", 4 for "beta", n+2 for "splines" with n nodes and the number of
levels minus one for "thresholds".
C. CAUTIONS REGARDING THE USE OF THE PROGRAM
Some caution should be made when using the program. convergence criteria are very strict as they are based on derivatives of the log-likelihood in addition to the parameter and log-likelihood stability. In some cases, the program may not converge and reach the maximum number of iterations fixed at 100. In this case, the user should check that parameter estimates at the last iteration are not on the boundaries of the parameter space. If the parameters are on the boundaries of the parameter space, the identifiability of the model is critical. This may happen especially with splines parameters that may be too close to 0 (lower boundary) or classmb parameters that are too high or low (perfect classification). When identifiability of some parameters is suspected, the program can be run again from the former estimates by fixing the suspected parameters to their value with option posfix. This usually solves the problem. An alternative is to remove the parameters of the Beta of Splines link function from the inverse of the Hessian with option partialH. If not, the program should be run again with other initial values, with a higher maximum number of iterations or less strict convergence tolerances.
Specifically when investigating heterogeneity (that is with ng>1): (1) As
the log-likelihood of a latent class model can have multiple maxima, a
careful choice of the initial values is crucial for ensuring convergence
toward the global maximum. The program can be run without entering the
vector of initial values (see point 2). However, we recommend to
systematically enter initial values in B and try different sets of
initial values. (2) The automatic choice of initial values we provide
requires the estimation of a preliminary linear mixed model. The user should
be aware that first, this preliminary analysis can take time for large
datatsets and second, that the generated initial values can be very not
likely and even may converge slowly to a local maximum. This is the reason
why several alternatives exist. The vector of initial values can be directly
specified in B the initial values can be generated (automatically or
randomly) from a model with ng=. Finally, function gridsearch
performs an automatic grid search.
D. NUMERICAL INTEGRATION WITH THE THRESHOLD LINK FUNCTION
With exception for the threshold link function, maximum likelihood estimation implemented in lcmm does not require any numerical integration over the random-effects so that the estimation procedure is relatively fast. See Proust et al. (2006) for more details on the estimation procedure.
However, with the threshold link function and when at least one random-effect is specified, a numerical integration over the random-effects distribution is required in each computation of the individual contribution to the likelihood which complicates greatly the estimation procedure. For the moment, we do not allow any option regarding the numerical integration technics used. 1. When a single random-effect is specified, we use a standard non-adaptive Gaussian quadrature with 30 points. 2. When at least two random-effects are specified, we use a multivariate non-adaptive Gaussian quadrature implemented by Genz (1996) in HRMSYM Fortran subroutine.
Further developments should allow for adaptive technics and more options regarding the numerical integration technic.
E. POSTERIOR DISCRETE LIKELIHOOD
Models involving nonlinear continuous link functions assume the continuous data while the model with a threshold model assumes discrete data. As a consequence, comparing likelihoods or criteria based on the likelihood (as AIC) for these models is not possible as the former are based on a Lebesgue measure and the latter on a counting measure. To make the comparison possible, we compute the posterior discrete likelihood for all the models with a nonlinear continuous link function. This posterior likelihood considers the data as discrete; it is computed at the MLE (maximum likelihood estimates) using the counting measure so that models with threshold or continuous link functions become comparable. Further details can be found in Proust-Lima, Amieva, Jacqmin-Gadda (2012).
In addition to the Akaike information criterion based on the discrete posterior likelihood, we also compute a universal approximate cross-validation criterion to compare models based on a different measure. See Commenges, Proust-Lima, Samieri, Liquet (2015) for further details.
Value
The list returned is:
ns |
number of grouping units in the dataset |
ng |
number of latent classes |
loglik |
log-likelihood of the model |
best |
vector of parameter estimates in the same order as
specified in |
V |
if the model converged (conv=1 or 3), vector containing the upper triangle
matrix of variance-covariance estimates of |
gconv |
vector of convergence criteria: 1. on the parameters, 2. on the likelihood, 3. on the derivatives |
conv |
status of convergence: =1 if the convergence criteria were satisfied, =2 if the maximum number of iterations was reached, =4 or 5 if a problem occured during optimisation |
call |
the matched call |
niter |
number of Marquardt iterations |
dataset |
dataset |
N |
internal information used in related functions |
idiag |
internal information used in related functions |
pred |
table of individual predictions and residuals in the
underlying latent process scale; it includes marginal predictions (pred_m),
marginal residuals (resid_m), subject-specific predictions (pred_ss) and
subject-specific residuals (resid_ss) averaged over classes, the transformed
observations in the latent process scale (obs) and finally the
class-specific marginal and subject-specific predictions (with the number of
the latent class: pred_m_1,pred_m_2,...,pred_ss_1,pred_ss_2,...). If |
pprob |
table of posterior classification and posterior individual class-membership probabilities |
Xnames |
list of covariates included in the model |
predRE |
table containing individual predictions of the random-effects : a column per random-effect, a line per subject. This output is not available yet when specifying a thresholds transformation. |
cholesky |
vector containing the estimates of the Cholesky transformed parameters of the variance-covariance matrix of the random-effects |
estimlink |
table containing the simulated values of the marker and corresponding estimated link function |
epsY |
definite positive real used to rescale the marker in (0,1) when the beta link function is used. By default, epsY=0.5. |
linktype |
indicator of link function type: 0 for linear, 1 for beta, 2 for splines and 3 for thresholds |
linknodes |
vector of nodes useful only for the 'splines' link function |
data |
the original data set (if returndata is TRUE) |
Author(s)
Cecile Proust-Lima, Amadou Diakite, Benoit Liquet and Viviane Philipps
References
Proust-Lima C, Philipps V, Liquet B (2017). Estimation of Extended Mixed Models Using Latent Classes and Latent Processes: The R Package lcmm. Journal of Statistical Software, 78(2), 1-56. doi:10.18637/jss.v078.i02
Genz and Keister (1996). Fully symmetric interpolatory rules for multiple integrals over infinite regions with gaussian weight. Journal of Computational and Applied Mathematics 71: 299-309.
Proust and Jacqmin-Gadda (2005). Estimation of linear mixed models with a mixture of distribution for the random-effects. Comput Methods Programs Biomed 78: 165-73.
Proust, Jacqmin-Gadda, Taylor, Ganiayre, and Commenges (2006). A nonlinear model with latent process for cognitive evolution using multivariate longitudinal data. Biometrics 62: 1014-24.
Proust-Lima, Dartigues and Jacqmin-Gadda (2011). Misuse of the linear mixed model when evaluating risk factors of cognitive decline. Amer J Epidemiol 174(9): 1077-88.
Proust-Lima, Amieva and Jacqmin-Gadda (2013). Analysis of multivariate mixed longitudinal data : a flexible latent process approach, British Journal of Mathematical and Statistical Psychology 66(3): 470-87.
Commenges, Proust-Lima, Samieri, Liquet (2015). A universal approximate cross-validation criterion for regular risk functions. Int J Biostat. 2015 May;11(1):51-67
See Also
postprob, plot.lcmm, plot.predict,
hlme
Examples
## Not run:
#### Estimation of homogeneous mixed models with different assumed link
#### functions, a quadratic mean trajectory for the latent process and
#### correlated random intercept and slope (the random quadratic slope
#### was removed as it did not improve the fit of the data).
#### -- comparison of linear, Beta and 3 different splines link functions --
# linear link function
m10<-lcmm(Ydep2~Time+I(Time^2),random=~Time,subject='ID',ng=1,
data=data_lcmm,link="linear")
summary(m10)
# Beta link function
m11<-lcmm(Ydep2~Time+I(Time^2),random=~Time,subject='ID',ng=1,
data=data_lcmm,link="beta")
summary(m11)
plot(m11,which="linkfunction",bty="l")
# I-splines with 3 equidistant nodes
m12<-lcmm(Ydep2~Time+I(Time^2),random=~Time,subject='ID',ng=1,
data=data_lcmm,link="3-equi-splines")
summary(m12)
# I-splines with 5 nodes at quantiles
m13<-lcmm(Ydep2~Time+I(Time^2),random=~Time,subject='ID',ng=1,
data=data_lcmm,link="5-quant-splines")
summary(m13)
# I-splines with 5 nodes, and interior nodes entered manually
m14<-lcmm(Ydep2~Time+I(Time^2),random=~Time,subject='ID',ng=1,
data=data_lcmm,link="5-manual-splines",intnodes=c(10,20,25))
summary(m14)
plot(m14,which="linkfunction",bty="l")
# Thresholds
# Especially for the threshold link function, we recommend to estimate
# models with increasing complexity and use estimates of previous ones
# to specify plausible initial values (we remind that estimation of
# models with threshold link function involves a computationally demanding
# numerical integration -here of size 3)
m15<-lcmm(Ydep2~Time+I(Time^2),random=~Time,subject='ID',ng=1
,data=data_lcmm,link="thresholds",maxiter=100,
B=c(-0.8379, -0.1103, 0.3832, 0.3788 , 0.4524, -7.3180, 0.5917, 0.7364,
0.6530, 0.4038, 0.4290, 0.6099, 0.6014 , 0.5354 , 0.5029 , 0.5463,
0.5310 , 0.5352, 0.6498, 0.6653, 0.5851, 0.6525, 0.6701 , 0.6670 ,
0.6767 , 0.7394 , 0.7426, 0.7153, 0.7702, 0.6421))
summary(m15)
plot(m15,which="linkfunction",bty="l")
#### Plot of estimated different link functions:
#### (applicable for models that only differ in the "link function" used.
#### Otherwise, the latent process scale is different and a rescaling
#### is necessary)
plot(m10,which="linkfunction",col=1,xlab="latent process",ylab="marker",
bty="l",xlim=c(-10,5),legend=NULL)
plot(m11,which="linkfunction",add=TRUE,col=2,legend=NULL)
plot(m12,which="linkfunction",add=TRUE,col=3,legend=NULL)
plot(m13,which="linkfunction",add=TRUE,col=4,legend=NULL)
plot(m14,which="linkfunction",add=TRUE,col=5,legend=NULL)
plot(m15,which="linkfunction",add=TRUE,col=6,legend=NULL)
legend(x="bottomright",legend=c("linear","beta","spl_3e","spl_5q","spl_5m","thresholds"),
col=1:6,lty=1,inset=.02,box.lty=0)
#### Estimation of 2-latent class mixed models with different assumed link
#### functions with individual and class specific linear trend
#### for illustration, only default initial values where used but other
#### sets of initial values should also be tried to ensure convergence
#### towards the golbal maximum
# Linear link function
m20<-lcmm(Ydep2~Time,random=~Time,subject='ID',mixture=~Time,ng=2,
idiag=TRUE,data=data_lcmm,link="linear",B=c(-0.98,0.79,-2.09,
-0.81,0.19,0.55,24.49,2.24))
summary(m20)
postprob(m20)
# Beta link function
m21<-lcmm(Ydep2~Time,random=~Time,subject='ID',mixture=~Time,ng=2,
idiag=TRUE,data=data_lcmm,link="beta",B=c(-0.1,-0.56,-0.4,-1.77,
0.53,0.14,0.6,-0.83,0.73,0.09))
summary(m21)
postprob(m21)
# I-splines link function (and 5 nodes at quantiles)
m22<-lcmm(Ydep2~Time,random=~Time,subject='ID',mixture=~Time,ng=2,
idiag=TRUE,data=data_lcmm,link="5-quant-splines",B=c(0.12,0.63,
-1.76,-0.39,0.51,0.13,-7.37,1.05,1.28,1.96,1.3,0.93,1.05))
summary(m22)
postprob(m22)
data <- data_lcmm[data_lcmm$ID==193,]
plot(predictL(m22,var.time="Time",newdata=data,bty="l")
## End(Not run)
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