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#' Quantile Regression for Continuous Dependent Variables
#'@param formula a symbolic representation of the model to be
#' estimated, in the form \code{y ~ x1 + x2}, where \code{y} is the
#' dependent variable and \code{x1} and \code{x2} are the explanatory
#' variables, and \code{y}, \code{x1}, and \code{x2} are contained in the
#' same dataset. (You may include more than two explanatory variables,
#' of course.) The \code{+} symbol means ``inclusion'' not
#' ``addition.'' You may also include interaction terms and main
#' effects in the form \code{x1*x2} without computing them in prior
#' steps; \code{I(x1*x2)} to include only the interaction term and
#' exclude the main effects; and quadratic terms in the form
#' \code{I(x1^2)}.
#'@param model the name of a statistical model to estimate.
#' For a list of other supported models and their documentation see:
#' \url{http://docs.zeligproject.org/articles/}.
#'@param data the name of a data frame containing the variables
#' referenced in the formula or a list of multiply imputed data frames
#' each having the same variable names and row numbers (created by
#' \code{Amelia} or \code{\link{to_zelig_mi}}).
#'@param ... additional arguments passed to \code{zelig},
#' relevant for the model to be estimated.
#'@param by a factor variable contained in \code{data}. If supplied,
#' \code{zelig} will subset
#' the data frame based on the levels in the \code{by} variable, and
#' estimate a model for each subset. This can save a considerable amount of
#' effort. You may also use \code{by} to run models using MatchIt
#' subclasses.
#'@param cite If is set to 'TRUE' (default), the model citation will be printed
#' to the console.
#'
#' @details
#' In addition to the standard inputs, \code{zelig} takes the following additional options
#' for quantile regression:
#' \itemize{
#' \item \code{tau}: defaults to 0.5. Specifies the conditional quantile(s) that will be
#' estimated. 0.5 corresponds to estimating the conditional median, 0.25 and 0.75 correspond
#' to the conditional quartiles, etc. tau vectors with length greater than 1 are not currently
#' supported. If tau is set outside of the interval [0,1], zelig returns the solution for all
#' possible conditional quantiles given the data, but does not support inference on this fit
#' (setx and sim will fail).
#' \item \code{se}: a string value that defaults to "nid". Specifies the method by which
#' the covariance matrix of coefficients is estimated during the sim stage of analysis. \code{se}
#' can take the following values, which are passed to the \code{summary.rq} function from the
#' \code{quantreg} package. These descriptions are copied from the \code{summary.rq} documentation.
#' \itemize{
#' \item \code{"iid"} which presumes that the errors are iid and computes an estimate of
#' the asymptotic covariance matrix as in KB(1978).
#' \item \code{"nid"} which presumes local (in tau) linearity (in x) of the the
#' conditional quantile functions and computes a Huber sandwich estimate using a local
#' estimate of the sparsity.
#' \item \code{"ker"} which uses a kernel estimate of the sandwich as proposed by Powell(1990).
#' }
#' \item \code{...}: additional options passed to rq when fitting the model. See documentation for rq in the quantreg package for more information.
#' }
#' Additional parameters avaialable to this model include:
#' \itemize{
#' \item \code{weights}: vector of weight values or a name of a variable in the dataset
#' by which to weight the model. For more information see:
#' \url{http://docs.zeligproject.org/articles/weights.html}.
#' \item \code{bootstrap}: logical or numeric. If \code{FALSE} don't use bootstraps to
#' robustly estimate uncertainty around model parameters due to sampling error.
#' If an integer is supplied, the number of boostraps to run.
#' For more information see:
#' \url{http://docs.zeligproject.org/articles/bootstraps.html}.
#' }
#'
#' @return Depending on the class of model selected, \code{zelig} will return
#' an object with elements including \code{coefficients}, \code{residuals},
#' and \code{formula} which may be summarized using
#' \code{summary(z.out)} or individually extracted using, for example,
#' \code{coef(z.out)}. See
#' \url{http://docs.zeligproject.org/articles/getters.html} for a list of
#' functions to extract model components. You can also extract whole fitted
#' model objects using \code{\link{from_zelig_model}}.
#'
#' @examples
#' library(Zelig)
#' data(stackloss)
#' z.out1 <- zelig(stack.loss ~ Air.Flow + Water.Temp + Acid.Conc.,
#' model = "rq", data = stackloss,tau = 0.5)
#' summary(z.out1)
#'
#' @seealso Vignette: \url{http://docs.zeligproject.org/articles/zelig_quantile.html}
#' @import methods
#' @export Zelig-quantile
#' @exportClass Zelig-quantile
#'
#' @include model-zelig.R
zquantile <- setRefClass("Zelig-quantile",
contains = "Zelig",
field = list(tau = "ANY"
))
zquantile$methods(
initialize = function() {
callSuper()
.self$fn <- quote(quantreg::rq)
.self$name <- "quantile"
.self$authors <- "Alexander D'Amour"
.self$packageauthors <- "Roger Koenker"
.self$modelauthors <- "Alexander D'Amour"
.self$year <- 2008
.self$category <- "continuous"
.self$description <- "Quantile Regression for Continuous Dependent Variables"
# JSON
.self$outcome <- "continuous"
.self$wrapper <- "rq"
.self$acceptweights <- TRUE
}
)
zquantile$methods(
zelig = function(formula, data, ..., weights = NULL, by = NULL,
bootstrap = FALSE) {
# avoids CRAN warning about deep assignment from formula existing separately as argument and field
localBy <- by
# avoids CRAN warning about deep assignment from formula existing separately as argument and field
localData <- data
.self$zelig.call <- match.call(expand.dots = TRUE)
.self$model.call <- match.call(expand.dots = TRUE)
if (!is.null(.self$model.call$tau)) {
if (length(eval(.self$model.call$tau)) > 1) {
stop('tau argument only accepts 1 value.\nZelig is using only the first value.',
call. = FALSE)
} else
.self$tau <- eval(.self$model.call$tau)
# if (length(.self$tau) > 1) {
# localData <- bind_rows(lapply(eval(.self$tau),
# function(tau) cbind(tau, localData)))
# # localBy <- cbind("tau", localBy)
# }
} else
.self$tau <- 0.5
callSuper(formula = formula, data = localData, ..., weights = weights,
by = localBy, bootstrap = bootstrap)
rq_summaries <- lapply(.self$zelig.out$z.out, (function(x)
summary(x, se = "nid", cov = TRUE)))
if (length(rq_summaries) > 1) {
rse <- lapply(rq_summaries, function(y) y$cov)
}
else rse <- rq_summaries$cov
# rse <- lapply(.self$zelig.out$z.out, (function(x)
# quantreg::summary.rq(x, se = "nid", cov = TRUE)$cov))
# rse <- lapply(.self$zelig.out$z.out,
# (function(x) {
# full <- quantreg::summary.rq(x, se = "nid", cov = TRUE)$cov
# })
# )
.self$test.statistics<- list(robust.se = rse)
})
zquantile$methods(
param = function(z.out, method = "mvn") {
object <- z.out
if(identical(method,"mvn")){
rq.sum <- summary(object, cov = TRUE, se = object$se)
return(mvrnorm(n = .self$num, mu = object$coef, Sigma = rq.sum$cov))
} else if(identical(method,"point")){
return(t(as.matrix(object$coef)))
}
})
zquantile$methods(
qi = function(simparam, mm) {
object <- mm
coeff <- simparam
eps <- .Machine$double.eps^(2/3)
ev <- coeff %*% t(object)
pv <- ev
n <- nrow(.self$data)
h <- bandwidth.rq(.self$tau, n) # estimate optimal bandwidth for sparsity
if (.self$tau + h > 1)
stop("tau + h > 1. Sparsity estimate failed. Please specify a tau closer to 0.5")
if (.self$tau - h < 0)
stop("tau - h < 0. Sparsity estimate failed. Please specify a tau closer to 0.5")
beta_high <- rq(.self$formula, data = .self$data, tau = .self$tau + h )$coef
beta_low <- rq(.self$formula, data = .self$data, tau = .self$tau - h)$coef
F_diff <- mm %*% (beta_high - beta_low)
if (any(F_diff <= 0))
warning(paste(sum(F_diff <= 0),
"density estimates were non-positive. Predicted values will likely be non-sensical."))
# Includes machine error correction as per summary.rq for nid case
f <- pmax(0, (2 * h) / (F_diff - eps))
# Use asymptotic approximation of Q(tau|X,beta) distribution
for(ii in 1:nrow(ev))
# Asymptotic distribution as per Koenker 2005 _Quantile Regression_ p. 72
pv[ii, ] <- rnorm(length(ev[ii, ]), mean = ev[ii, ],
sqrt((.self$tau * (1 - .self$tau))) / (f * sqrt(n)))
return(list(ev = ev, pv = pv))
}
)
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