kalcount: Repeated Measurements Models for Counts with Frailty or...
In swihart/repeated: Non-Normal Repeated Measurements Models
kalcount R Documentation
Repeated Measurements Models for Counts with Frailty or Serial Dependence
Description
kalcount is designed to handle repeated measurements models with
time-varying covariates. The distributions have two extra parameters as
compared to the functions specified by intensity and are generally
longer tailed than those distributions. Dependence among observations on a
unit can be through gamma or power variance family frailties (a type of
random effect), with or without autoregression, or serial dependence over
time.
Usage
kalcount(
response = NULL,
times = NULL,
origin = 0,
intensity = "exponential",
depend = "independence",
update = "Markov",
mu = NULL,
shape = NULL,
density = FALSE,
ccov = NULL,
tvcov = NULL,
preg = NULL,
ptvc = NULL,
pbirth = NULL,
pintercept = NULL,
pshape = NULL,
pinitial = 1,
pdepend = NULL,
pfamily = NULL,
envir = parent.frame(),
print.level = 0,
ndigit = 10,
gradtol = 1e-05,
steptol = 1e-05,
fscale = 1,
iterlim = 100,
typsize = abs(p),
stepmax = 10 * sqrt(p %*% p)
)
Arguments
response
A list of two column matrices with counts and corresponding
times for each individual, one matrix or dataframe of counts, or an object
of class, response (created by restovec) or
repeated (created by rmna or
lvna). If the repeated data object contains
more than one response variable, give that object in envir and give
the name of the response variable to be used here.
times
When response is a matrix, a vector of possibly unequally
spaced times when they are the same for all individuals or a matrix of
times. Not necessary if equally spaced. Ignored if response has class,
response or repeated.
origin
If the time origin is to be before the start of observations,
a positive constant to be added to all times.
intensity
The form of function to be put in the Pareto distribution.
Choices are exponential, Weibull, gamma, log normal, log logistic, log
Cauchy, log Student, and gen(eralized) logistic.
depend
Type of dependence. Choices are independence,
frailty, and serial.
update
Type of for serial dependence. Choices are Markov,
serial, event, cumulated, count, and
kalman. With frailty dependence, weighting by length of
observation time may be specified by setting update to time.
mu
A regression function for the location parameter or a formula
beginning with ~, specifying either a linear regression function in the
Wilkinson and Rogers notation (a log link is assumed) or a general function
with named unknown parameters. Give the initial estimates in preg if
there are no time-varying covariates and in ptvc if there are.
shape
A regression function for the shape parameter or a formula
beginning with ~, specifying either a linear regression function in the
Wilkinson and Rogers notation or a general function with named unknown
parameters. It must yield one value per observation.
density
If TRUE, the density of the function specified in
intensity is used instead of the intensity.
ccov
A vector or matrix containing time-constant baseline covariates
with one row per individual, a model formula using vectors of the same
size, or an object of class, tccov (created by
tcctomat). If response has class, repeated,
the covariates must be supplied as a Wilkinson and Rogers formula unless
none are to be used or mu is given.
tvcov
A list of matrices with time-varying covariate values,
observed in the time periods in response, for each individual (one
column per variable), one matrix or dataframe of such covariate values, or
an object of class, tvcov (created by
tvctomat). If response has class, repeated,
the covariates must be supplied as a Wilkinson and Rogers formula unless
none are to be used or mu is given.
preg
Initial parameter estimates for the regression model: intercept
plus one for each covariate in ccov. If mu is a formula or
function, the parameter estimates must be given here only if there are no
time-varying covariates. If mu is a formula with unknown parameters,
their estimates must be supplied either in their order of appearance in the
expression or in a named list.
ptvc
Initial parameter estimates for the coefficients of the
time-varying covariates, as many as in tvcov. If mu is a
formula or function, the parameter estimates must be given here if there
are time-varying covariates present.
pbirth
If supplied, this is the initial estimate for the coefficient
of the birth model.
pintercept
The initial estimate of the intercept for the generalized
logistic intensity.
pshape
An initial estimate for the shape parameter of the intensity
function (except exponential intensity). If shape is a function or
formula, the corresponding initial estimates. If shape is a formula
with unknown parameters, their estimates must be supplied either in their
order of appearance in the expression or in a named list.
pinitial
An initial estimate for the initial parameter. With
frailty dependence, this is the frailty parameter.
pdepend
An initial estimate for the serial dependence parameter. For
frailty dependence, if a value is given here, an autoregression is
fitted as well as the frailty.
pfamily
An optional initial estimate for the second parameter of a
two-parameter power variance family mixture instead of the default gamma
mixture. This yields a gamma mixture as family -> 0, an inverse
Gauss mixture for family = 0.5, and a compound distribution of a
Poisson-distributed number of gamma distributions for -1 < family <
0.
envir
Environment in which model formulae are to be interpreted or a
data object of class, repeated, tccov, or tvcov; the
name of the response variable should be given in response. If
response has class repeated, it is used as the environment.
print.level
Arguments for nlm.
ndigit
Arguments for nlm.
gradtol
Arguments for nlm.
steptol
Arguments for nlm.
fscale
Arguments for nlm.
iterlim
Arguments for nlm.
typsize
Arguments for nlm.
stepmax
Arguments for nlm.
Details
By default, a gamma mixture of the distribution specified in
intensity is used, as the conditional distribution in the
serial dependence models, and as a symmetric multivariate (random
effect) model for frailty dependence.
Unless specified otherwise, the time origin is taken to be zero. The given
times are the ends of the periods in which the counts occurred.
Here, the variance, with exponential intensity, is a quadratic function of
the mean, whereas, for nbkal, it is proportional to
the mean function.
If the counts on a unit are clustered, not longitudinal, use the failty
dependence with the default exponential intensity, yielding a multivariate
negative binomial distribution.
Nonlinear regression models can be supplied as formulae where parameters
are unknowns in which case factor variables cannot be used and parameters
must be scalars. (See finterp.)
Marginal and individual profiles can be plotted using
mprofile and iprofile and
residuals with plot.residuals.
Value
A list of classes kalcount and recursive is returned.
Author(s)
J.K. Lindsey
Examples
treat <- c(0,0,1,1)
tr <- tcctomat(treat)
dose <-
matrix(c(9,13,16,7,12,6,9,10,11,9,10,10,7,9,9,9,8,10,15,4),
ncol=5,byrow=TRUE)
dd <- tvctomat(dose)
y <- restovec(structure(c(6, 4, 0, 0, 3, 6, 1, 1, 1, 5, 0, 0, 0, 4, 0, 1, 0,
13, 0, 3), dim = 4:5))
reps <- rmna(y, ccov=tr, tvcov=dd)
kalcount(y, intensity="log normal", dep="independence",
preg=0.3, pshape=0.1)
kalcount(y, intensity="log normal", dep="frailty", pinitial=0.1,
preg=1, psh=0.1)
kalcount(y, intensity="log normal", dep="serial", pinitial=0.1,
preg=1, pdep=0.75, psh=0.1)
# random effect and autoregression (commented out: AR difficult to estimate)
#kalcount(y, intensity="log normal", dep="frailty", pinitial=0.1,
# pdep=0.5, preg=1, psh=0.1)
# add time-constant variable
kalcount(y, intensity="log normal", pinitial=1, psh=1,
preg=c(0.8,0.11), ccov=treat)
# or
kalcount(y, intensity="log normal", mu=~b0+b1*treat,
pinitial=1, psh=.1, preg=c(0.4,-0.04), envir=reps)
# add time-varying variable
kalcount(y, intensity="log normal", pinitial=1, psh=1,
preg=c(-1,2), ccov=treat, ptvc=0, tvc=dose)
# or equivalently, from the environment
dosev <- as.vector(t(dose))
kalcount(y, intensity="log normal", mu=~b0+b1*rep(treat,rep(5,4))+b2*dosev,
pinitial=1, psh=1, ptvc=c(-1,2,0))
# or from the reps data object
kalcount(y, intensity="log normal", mu=~b0+b1*treat+b2*dose,
pinitial=1, psh=1, ptvc=c(-1,2,0), envir=reps)
# try power variance family
kalcount(y, intensity="log normal", mu=~b0+b1*treat+b2*dose,
pinitial=1, psh=1, ptvc=c(-1,2,0.1), envir=reps,
pfamily=0.8)
swihart/repeated documentation built on Aug. 25, 2023, 12:34 p.m.
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| kalcount | R Documentation |
Repeated Measurements Models for Counts with Frailty or Serial Dependence
Description
kalcount is designed to handle repeated measurements models with
time-varying covariates. The distributions have two extra parameters as
compared to the functions specified by intensity and are generally
longer tailed than those distributions. Dependence among observations on a
unit can be through gamma or power variance family frailties (a type of
random effect), with or without autoregression, or serial dependence over
time.
Usage
kalcount(
response = NULL,
times = NULL,
origin = 0,
intensity = "exponential",
depend = "independence",
update = "Markov",
mu = NULL,
shape = NULL,
density = FALSE,
ccov = NULL,
tvcov = NULL,
preg = NULL,
ptvc = NULL,
pbirth = NULL,
pintercept = NULL,
pshape = NULL,
pinitial = 1,
pdepend = NULL,
pfamily = NULL,
envir = parent.frame(),
print.level = 0,
ndigit = 10,
gradtol = 1e-05,
steptol = 1e-05,
fscale = 1,
iterlim = 100,
typsize = abs(p),
stepmax = 10 * sqrt(p %*% p)
)
Arguments
response |
A list of two column matrices with counts and corresponding
times for each individual, one matrix or dataframe of counts, or an object
of class, |
times |
When response is a matrix, a vector of possibly unequally
spaced times when they are the same for all individuals or a matrix of
times. Not necessary if equally spaced. Ignored if response has class,
|
origin |
If the time origin is to be before the start of observations, a positive constant to be added to all times. |
intensity |
The form of function to be put in the Pareto distribution. Choices are exponential, Weibull, gamma, log normal, log logistic, log Cauchy, log Student, and gen(eralized) logistic. |
depend |
Type of dependence. Choices are |
update |
Type of for serial dependence. Choices are |
mu |
A regression function for the location parameter or a formula
beginning with ~, specifying either a linear regression function in the
Wilkinson and Rogers notation (a log link is assumed) or a general function
with named unknown parameters. Give the initial estimates in |
shape |
A regression function for the shape parameter or a formula beginning with ~, specifying either a linear regression function in the Wilkinson and Rogers notation or a general function with named unknown parameters. It must yield one value per observation. |
density |
If TRUE, the density of the function specified in
|
ccov |
A vector or matrix containing time-constant baseline covariates
with one row per individual, a model formula using vectors of the same
size, or an object of class, |
tvcov |
A list of matrices with time-varying covariate values,
observed in the time periods in |
preg |
Initial parameter estimates for the regression model: intercept
plus one for each covariate in |
ptvc |
Initial parameter estimates for the coefficients of the
time-varying covariates, as many as in |
pbirth |
If supplied, this is the initial estimate for the coefficient of the birth model. |
pintercept |
The initial estimate of the intercept for the generalized logistic intensity. |
pshape |
An initial estimate for the shape parameter of the intensity
function (except exponential intensity). If |
pinitial |
An initial estimate for the initial parameter. With
|
pdepend |
An initial estimate for the serial dependence parameter. For
|
pfamily |
An optional initial estimate for the second parameter of a
two-parameter power variance family mixture instead of the default gamma
mixture. This yields a gamma mixture as |
envir |
Environment in which model formulae are to be interpreted or a
data object of class, |
print.level |
Arguments for nlm. |
ndigit |
Arguments for nlm. |
gradtol |
Arguments for nlm. |
steptol |
Arguments for nlm. |
fscale |
Arguments for nlm. |
iterlim |
Arguments for nlm. |
typsize |
Arguments for nlm. |
stepmax |
Arguments for nlm. |
Details
By default, a gamma mixture of the distribution specified in
intensity is used, as the conditional distribution in the
serial dependence models, and as a symmetric multivariate (random
effect) model for frailty dependence.
Unless specified otherwise, the time origin is taken to be zero. The given times are the ends of the periods in which the counts occurred.
Here, the variance, with exponential intensity, is a quadratic function of
the mean, whereas, for nbkal, it is proportional to
the mean function.
If the counts on a unit are clustered, not longitudinal, use the failty dependence with the default exponential intensity, yielding a multivariate negative binomial distribution.
Nonlinear regression models can be supplied as formulae where parameters
are unknowns in which case factor variables cannot be used and parameters
must be scalars. (See finterp.)
Marginal and individual profiles can be plotted using
mprofile and iprofile and
residuals with plot.residuals.
Value
A list of classes kalcount and recursive is returned.
Author(s)
J.K. Lindsey
Examples
treat <- c(0,0,1,1)
tr <- tcctomat(treat)
dose <-
matrix(c(9,13,16,7,12,6,9,10,11,9,10,10,7,9,9,9,8,10,15,4),
ncol=5,byrow=TRUE)
dd <- tvctomat(dose)
y <- restovec(structure(c(6, 4, 0, 0, 3, 6, 1, 1, 1, 5, 0, 0, 0, 4, 0, 1, 0,
13, 0, 3), dim = 4:5))
reps <- rmna(y, ccov=tr, tvcov=dd)
kalcount(y, intensity="log normal", dep="independence",
preg=0.3, pshape=0.1)
kalcount(y, intensity="log normal", dep="frailty", pinitial=0.1,
preg=1, psh=0.1)
kalcount(y, intensity="log normal", dep="serial", pinitial=0.1,
preg=1, pdep=0.75, psh=0.1)
# random effect and autoregression (commented out: AR difficult to estimate)
#kalcount(y, intensity="log normal", dep="frailty", pinitial=0.1,
# pdep=0.5, preg=1, psh=0.1)
# add time-constant variable
kalcount(y, intensity="log normal", pinitial=1, psh=1,
preg=c(0.8,0.11), ccov=treat)
# or
kalcount(y, intensity="log normal", mu=~b0+b1*treat,
pinitial=1, psh=.1, preg=c(0.4,-0.04), envir=reps)
# add time-varying variable
kalcount(y, intensity="log normal", pinitial=1, psh=1,
preg=c(-1,2), ccov=treat, ptvc=0, tvc=dose)
# or equivalently, from the environment
dosev <- as.vector(t(dose))
kalcount(y, intensity="log normal", mu=~b0+b1*rep(treat,rep(5,4))+b2*dosev,
pinitial=1, psh=1, ptvc=c(-1,2,0))
# or from the reps data object
kalcount(y, intensity="log normal", mu=~b0+b1*treat+b2*dose,
pinitial=1, psh=1, ptvc=c(-1,2,0), envir=reps)
# try power variance family
kalcount(y, intensity="log normal", mu=~b0+b1*treat+b2*dose,
pinitial=1, psh=1, ptvc=c(-1,2,0.1), envir=reps,
pfamily=0.8)
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