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-rw-r--r--R/endpoints.R8
-rw-r--r--R/plot.mixed.mmkin.R23
-rw-r--r--R/saem.R512
-rw-r--r--R/summary.saem.mmkin.R268
4 files changed, 806 insertions, 5 deletions
diff --git a/R/endpoints.R b/R/endpoints.R
index b5872e68..f1f47581 100644
--- a/R/endpoints.R
+++ b/R/endpoints.R
@@ -10,8 +10,8 @@
#' Additional DT50 values are calculated from the FOMC DT90 and k1 and k2 from
#' HS and DFOP, as well as from Eigenvalues b1 and b2 of any SFORB models
#'
-#' @param fit An object of class [mkinfit] or [nlme.mmkin]
-#' or another object that has list components
+#' @param fit An object of class [mkinfit], [nlme.mmkin] or
+#' [saem.mmkin]. Or another object that has list components
#' mkinmod containing an [mkinmod] degradation model, and two numeric vectors,
#' bparms.optim and bparms.fixed, that contain parameter values
#' for that model.
@@ -20,8 +20,8 @@
#' and, if applicable, a vector of formation fractions named ff
#' and, if the SFORB model was in use, a vector of eigenvalues
#' of these SFORB models, equivalent to DFOP rate constants
-#' @note The function is used internally by [summary.mkinfit]
-#' and [summary.nlme.mmkin]
+#' @note The function is used internally by [summary.mkinfit],
+#' [summary.nlme.mmkin] and [summary.saem.mmkin].
#' @author Johannes Ranke
#' @examples
#'
diff --git a/R/plot.mixed.mmkin.R b/R/plot.mixed.mmkin.R
index 4c1f1531..21399496 100644
--- a/R/plot.mixed.mmkin.R
+++ b/R/plot.mixed.mmkin.R
@@ -2,7 +2,7 @@ utils::globalVariables("ds")
#' Plot predictions from a fitted nonlinear mixed model obtained via an mmkin row object
#'
-#' @param x An object of class [mixed.mmkin], [nlme.mmkin]
+#' @param x An object of class [mixed.mmkin], [saem.mmkin] or [nlme.mmkin]
#' @param i A numeric index to select datasets for which to plot the individual predictions,
#' in case plots get too large
#' @inheritParams plot.mkinfit
@@ -39,6 +39,15 @@ utils::globalVariables("ds")
#' f_nlme <- nlme(f, control = list(pnlsMaxIter = 120, tolerance = 1e-3))
#' plot(f_nlme)
#'
+#' f_saem <- saem(f, transformations = "saemix")
+#' plot(f_saem)
+#'
+#' # We can overlay the two variants if we generate predictions
+#' pred_nlme <- mkinpredict(dfop_sfo,
+#' f_nlme$bparms.optim[-1],
+#' c(parent = f_nlme$bparms.optim[[1]], A1 = 0),
+#' seq(0, 180, by = 0.2))
+#' plot(f_saem, pred_over = list(nlme = pred_nlme))
#' }
#' @export
plot.mixed.mmkin <- function(x,
@@ -82,6 +91,18 @@ plot.mixed.mmkin <- function(x,
type = ifelse(standardized, "pearson", "response"))
}
+ if (inherits(x, "saem.mmkin")) {
+ if (x$transformations == "saemix") backtransform = FALSE
+ degparms_i <- saemix::psi(x$so)
+ rownames(degparms_i) <- ds_names
+ degparms_i_names <- setdiff(x$so@results@name.fixed, names(fit_1$errparms))
+ colnames(degparms_i) <- degparms_i_names
+ residual_type = ifelse(standardized, "standardized", "residual")
+ residuals <- x$data[[residual_type]]
+ degparms_pop <- x$so@results@fixed.effects
+ names(degparms_pop) <- degparms_i_names
+ }
+
degparms_fixed <- fit_1$fixed$value
names(degparms_fixed) <- rownames(fit_1$fixed)
degparms_all <- cbind(as.matrix(degparms_i),
diff --git a/R/saem.R b/R/saem.R
new file mode 100644
index 00000000..fd2a77b4
--- /dev/null
+++ b/R/saem.R
@@ -0,0 +1,512 @@
+utils::globalVariables(c("predicted", "std"))
+
+#' Fit nonlinear mixed models with SAEM
+#'
+#' This function uses [saemix::saemix()] as a backend for fitting nonlinear mixed
+#' effects models created from [mmkin] row objects using the Stochastic Approximation
+#' Expectation Maximisation algorithm (SAEM).
+#'
+#' An mmkin row object is essentially a list of mkinfit objects that have been
+#' obtained by fitting the same model to a list of datasets using [mkinfit].
+#'
+#' Starting values for the fixed effects (population mean parameters, argument
+#' psi0 of [saemix::saemixModel()] are the mean values of the parameters found
+#' using [mmkin].
+#'
+#' @param object An [mmkin] row object containing several fits of the same
+#' [mkinmod] model to different datasets
+#' @param verbose Should we print information about created objects of
+#' type [saemix::SaemixModel] and [saemix::SaemixData]?
+#' @param transformations Per default, all parameter transformations are done
+#' in mkin. If this argument is set to 'saemix', parameter transformations
+#' are done in 'saemix' for the supported cases. Currently this is only
+#' supported in cases where the initial concentration of the parent is not fixed,
+#' SFO or DFOP is used for the parent and there is either no metabolite or one.
+#' @param degparms_start Parameter values given as a named numeric vector will
+#' be used to override the starting values obtained from the 'mmkin' object.
+#' @param solution_type Possibility to specify the solution type in case the
+#' automatic choice is not desired
+#' @param quiet Should we suppress the messages saemix prints at the beginning
+#' and the end of the optimisation process?
+#' @param control Passed to [saemix::saemix]
+#' @param \dots Further parameters passed to [saemix::saemixModel].
+#' @return An S3 object of class 'saem.mmkin', containing the fitted
+#' [saemix::SaemixObject] as a list component named 'so'. The
+#' object also inherits from 'mixed.mmkin'.
+#' @seealso [summary.saem.mmkin] [plot.mixed.mmkin]
+#' @examples
+#' \dontrun{
+#' ds <- lapply(experimental_data_for_UBA_2019[6:10],
+#' function(x) subset(x$data[c("name", "time", "value")]))
+#' names(ds) <- paste("Dataset", 6:10)
+#' f_mmkin_parent_p0_fixed <- mmkin("FOMC", ds,
+#' state.ini = c(parent = 100), fixed_initials = "parent", quiet = TRUE)
+#' f_saem_p0_fixed <- saem(f_mmkin_parent_p0_fixed)
+#'
+#' f_mmkin_parent <- mmkin(c("SFO", "FOMC", "DFOP"), ds, quiet = TRUE)
+#' f_saem_sfo <- saem(f_mmkin_parent["SFO", ])
+#' f_saem_fomc <- saem(f_mmkin_parent["FOMC", ])
+#' f_saem_dfop <- saem(f_mmkin_parent["DFOP", ])
+#'
+#' # The returned saem.mmkin object contains an SaemixObject, therefore we can use
+#' # functions from saemix
+#' library(saemix)
+#' compare.saemix(list(f_saem_sfo$so, f_saem_fomc$so, f_saem_dfop$so))
+#' plot(f_saem_fomc$so, plot.type = "convergence")
+#' plot(f_saem_fomc$so, plot.type = "individual.fit")
+#' plot(f_saem_fomc$so, plot.type = "npde")
+#' plot(f_saem_fomc$so, plot.type = "vpc")
+#'
+#' f_mmkin_parent_tc <- update(f_mmkin_parent, error_model = "tc")
+#' f_saem_fomc_tc <- saem(f_mmkin_parent_tc["FOMC", ])
+#' compare.saemix(list(f_saem_fomc$so, f_saem_fomc_tc$so))
+#'
+#' sfo_sfo <- mkinmod(parent = mkinsub("SFO", "A1"),
+#' A1 = mkinsub("SFO"))
+#' fomc_sfo <- mkinmod(parent = mkinsub("FOMC", "A1"),
+#' A1 = mkinsub("SFO"))
+#' dfop_sfo <- mkinmod(parent = mkinsub("DFOP", "A1"),
+#' A1 = mkinsub("SFO"))
+#' # The following fit uses analytical solutions for SFO-SFO and DFOP-SFO,
+#' # and compiled ODEs for FOMC that are much slower
+#' f_mmkin <- mmkin(list(
+#' "SFO-SFO" = sfo_sfo, "FOMC-SFO" = fomc_sfo, "DFOP-SFO" = dfop_sfo),
+#' ds, quiet = TRUE)
+#' # saem fits of SFO-SFO and DFOP-SFO to these data take about five seconds
+#' # each on this system, as we use analytical solutions written for saemix.
+#' # When using the analytical solutions written for mkin this took around
+#' # four minutes
+#' f_saem_sfo_sfo <- saem(f_mmkin["SFO-SFO", ])
+#' f_saem_dfop_sfo <- saem(f_mmkin["DFOP-SFO", ])
+#' # We can use print, plot and summary methods to check the results
+#' print(f_saem_dfop_sfo)
+#' plot(f_saem_dfop_sfo)
+#' summary(f_saem_dfop_sfo, data = TRUE)
+#'
+#' # The following takes about 6 minutes
+#' #f_saem_dfop_sfo_deSolve <- saem(f_mmkin["DFOP-SFO", ], solution_type = "deSolve",
+#' # control = list(nbiter.saemix = c(200, 80), nbdisplay = 10))
+#'
+#' #saemix::compare.saemix(list(
+#' # f_saem_dfop_sfo$so,
+#' # f_saem_dfop_sfo_deSolve$so))
+#'
+#' # If the model supports it, we can also use eigenvalue based solutions, which
+#' # take a similar amount of time
+#' #f_saem_sfo_sfo_eigen <- saem(f_mmkin["SFO-SFO", ], solution_type = "eigen",
+#' # control = list(nbiter.saemix = c(200, 80), nbdisplay = 10))
+#' }
+#' @export
+saem <- function(object, ...) UseMethod("saem")
+
+#' @rdname saem
+#' @export
+saem.mmkin <- function(object,
+ transformations = c("mkin", "saemix"),
+ degparms_start = numeric(),
+ solution_type = "auto",
+ control = list(displayProgress = FALSE, print = FALSE,
+ save = FALSE, save.graphs = FALSE),
+ verbose = FALSE, quiet = FALSE, ...)
+{
+ transformations <- match.arg(transformations)
+ m_saemix <- saemix_model(object, verbose = verbose,
+ degparms_start = degparms_start, solution_type = solution_type,
+ transformations = transformations, ...)
+ d_saemix <- saemix_data(object, verbose = verbose)
+
+ fit_time <- system.time({
+ utils::capture.output(f_saemix <- saemix::saemix(m_saemix, d_saemix, control), split = !quiet)
+ })
+
+ transparms_optim <- f_saemix@results@fixed.effects
+ names(transparms_optim) <- f_saemix@results@name.fixed
+
+ if (transformations == "mkin") {
+ bparms_optim <- backtransform_odeparms(transparms_optim,
+ object[[1]]$mkinmod,
+ object[[1]]$transform_rates,
+ object[[1]]$transform_fractions)
+ } else {
+ bparms_optim <- transparms_optim
+ }
+
+ return_data <- nlme_data(object)
+
+ return_data$predicted <- f_saemix@model@model(
+ psi = saemix::psi(f_saemix),
+ id = as.numeric(return_data$ds),
+ xidep = return_data[c("time", "name")])
+
+ return_data <- transform(return_data,
+ residual = predicted - value,
+ std = sigma_twocomp(predicted,
+ f_saemix@results@respar[1], f_saemix@results@respar[2]))
+ return_data <- transform(return_data,
+ standardized = residual / std)
+
+ result <- list(
+ mkinmod = object[[1]]$mkinmod,
+ mmkin = object,
+ solution_type = object[[1]]$solution_type,
+ transformations = transformations,
+ transform_rates = object[[1]]$transform_rates,
+ transform_fractions = object[[1]]$transform_fractions,
+ so = f_saemix,
+ time = fit_time,
+ mean_dp_start = attr(m_saemix, "mean_dp_start"),
+ bparms.optim = bparms_optim,
+ bparms.fixed = object[[1]]$bparms.fixed,
+ data = return_data,
+ err_mod = object[[1]]$err_mod,
+ date.fit = date(),
+ saemixversion = as.character(utils::packageVersion("saemix")),
+ mkinversion = as.character(utils::packageVersion("mkin")),
+ Rversion = paste(R.version$major, R.version$minor, sep=".")
+ )
+
+ class(result) <- c("saem.mmkin", "mixed.mmkin")
+ return(result)
+}
+
+#' @export
+#' @rdname saem
+#' @param x An saem.mmkin object to print
+#' @param digits Number of digits to use for printing
+print.saem.mmkin <- function(x, digits = max(3, getOption("digits") - 3), ...) {
+ cat( "Kinetic nonlinear mixed-effects model fit by SAEM" )
+ cat("\nStructural model:\n")
+ diffs <- x$mmkin[[1]]$mkinmod$diffs
+ nice_diffs <- gsub("^(d.*) =", "\\1/dt =", diffs)
+ writeLines(strwrap(nice_diffs, exdent = 11))
+ cat("\nData:\n")
+ cat(nrow(x$data), "observations of",
+ length(unique(x$data$name)), "variable(s) grouped in",
+ length(unique(x$data$ds)), "datasets\n")
+
+ cat("\nLikelihood computed by importance sampling\n")
+ print(data.frame(
+ AIC = AIC(x$so, type = "is"),
+ BIC = BIC(x$so, type = "is"),
+ logLik = logLik(x$so, type = "is"),
+ row.names = " "), digits = digits)
+
+ cat("\nFitted parameters:\n")
+ conf.int <- x$so@results@conf.int[c("estimate", "lower", "upper")]
+ rownames(conf.int) <- x$so@results@conf.int[["name"]]
+ print(conf.int, digits = digits)
+
+ invisible(x)
+}
+
+#' @rdname saem
+#' @return An [saemix::SaemixModel] object.
+#' @export
+saemix_model <- function(object, solution_type = "auto", transformations = c("mkin", "saemix"),
+ degparms_start = numeric(), verbose = FALSE, ...)
+{
+ if (nrow(object) > 1) stop("Only row objects allowed")
+
+ mkin_model <- object[[1]]$mkinmod
+
+ degparms_optim <- mean_degparms(object)
+ if (transformations == "saemix") {
+ degparms_optim <- backtransform_odeparms(degparms_optim,
+ object[[1]]$mkinmod,
+ object[[1]]$transform_rates,
+ object[[1]]$transform_fractions)
+ }
+ degparms_fixed <- object[[1]]$bparms.fixed
+
+ # Transformations are done in the degradation function
+ transform.par = rep(0, length(degparms_optim))
+
+ odeini_optim_parm_names <- grep('_0$', names(degparms_optim), value = TRUE)
+ odeini_fixed_parm_names <- grep('_0$', names(degparms_fixed), value = TRUE)
+
+ odeparms_fixed_names <- setdiff(names(degparms_fixed), odeini_fixed_parm_names)
+ odeparms_fixed <- degparms_fixed[odeparms_fixed_names]
+
+ odeini_fixed <- degparms_fixed[odeini_fixed_parm_names]
+ names(odeini_fixed) <- gsub('_0$', '', odeini_fixed_parm_names)
+
+ model_function <- FALSE
+
+ # Model functions with analytical solutions
+ # Fixed parameters, use_of_ff = "min" and turning off sinks currently not supported here
+ # In general, we need to consider exactly how the parameters in mkinfit were specified,
+ # as the parameters are currently mapped by position in these solutions
+ sinks <- sapply(mkin_model$spec, function(x) x$sink)
+ if (length(odeparms_fixed) == 0 & mkin_model$use_of_ff == "max" & all(sinks)) {
+ # Parent only
+ if (length(mkin_model$spec) == 1) {
+ parent_type <- mkin_model$spec[[1]]$type
+ if (length(odeini_fixed) == 1) {
+ if (parent_type == "SFO") {
+ stop("saemix needs at least two parameters to work on.")
+ }
+ if (parent_type == "FOMC") {
+ model_function <- function(psi, id, xidep) {
+ odeini_fixed / (xidep[, "time"]/exp(psi[id, 2]) + 1)^exp(psi[id, 1])
+ }
+ }
+ if (parent_type == "DFOP") {
+ model_function <- function(psi, id, xidep) {
+ g <- plogis(psi[id, 3])
+ t <- xidep[, "time"]
+ odeini_fixed * (g * exp(- exp(psi[id, 1]) * t) +
+ (1 - g) * exp(- exp(psi[id, 2]) * t))
+ }
+ }
+ if (parent_type == "HS") {
+ model_function <- function(psi, id, xidep) {
+ tb <- exp(psi[id, 3])
+ t <- xidep[, "time"]
+ k1 = exp(psi[id, 1])
+ odeini_fixed * ifelse(t <= tb,
+ exp(- k1 * t),
+ exp(- k1 * tb) * exp(- exp(psi[id, 2]) * (t - tb)))
+ }
+ }
+ } else {
+ if (parent_type == "SFO") {
+ if (transformations == "mkin") {
+ model_function <- function(psi, id, xidep) {
+ psi[id, 1] * exp( - exp(psi[id, 2]) * xidep[, "time"])
+ }
+ } else {
+ model_function <- function(psi, id, xidep) {
+ psi[id, 1] * exp( - psi[id, 2] * xidep[, "time"])
+ }
+ transform.par = c(0, 1)
+ }
+ }
+ if (parent_type == "FOMC") {
+ model_function <- function(psi, id, xidep) {
+ psi[id, 1] / (xidep[, "time"]/exp(psi[id, 3]) + 1)^exp(psi[id, 2])
+ }
+ }
+ if (parent_type == "DFOP") {
+ if (transformations == "mkin") {
+ model_function <- function(psi, id, xidep) {
+ g <- plogis(psi[id, 4])
+ t <- xidep[, "time"]
+ psi[id, 1] * (g * exp(- exp(psi[id, 2]) * t) +
+ (1 - g) * exp(- exp(psi[id, 3]) * t))
+ }
+ } else {
+ model_function <- function(psi, id, xidep) {
+ g <- psi[id, 4]
+ t <- xidep[, "time"]
+ psi[id, 1] * (g * exp(- psi[id, 2] * t) +
+ (1 - g) * exp(- psi[id, 3] * t))
+ }
+ transform.par = c(0, 1, 1, 3)
+ }
+ }
+ if (parent_type == "HS") {
+ model_function <- function(psi, id, xidep) {
+ tb <- exp(psi[id, 4])
+ t <- xidep[, "time"]
+ k1 = exp(psi[id, 2])
+ psi[id, 1] * ifelse(t <= tb,
+ exp(- k1 * t),
+ exp(- k1 * tb) * exp(- exp(psi[id, 3]) * (t - tb)))
+ }
+ }
+ }
+ }
+
+ # Parent with one metabolite
+ # Parameter names used in the model functions are as in
+ # https://nbviewer.jupyter.org/urls/jrwb.de/nb/Symbolic%20ODE%20solutions%20for%20mkin.ipynb
+ types <- unname(sapply(mkin_model$spec, function(x) x$type))
+ if (length(mkin_model$spec) == 2 &! "SFORB" %in% types ) {
+ # Initial value for the metabolite (n20) must be fixed
+ if (names(odeini_fixed) == names(mkin_model$spec)[2]) {
+ n20 <- odeini_fixed
+ parent_name <- names(mkin_model$spec)[1]
+ if (identical(types, c("SFO", "SFO"))) {
+ if (transformations == "mkin") {
+ model_function <- function(psi, id, xidep) {
+ t <- xidep[, "time"]
+ n10 <- psi[id, 1]
+ k1 <- exp(psi[id, 2])
+ k2 <- exp(psi[id, 3])
+ f12 <- plogis(psi[id, 4])
+ ifelse(xidep[, "name"] == parent_name,
+ n10 * exp(- k1 * t),
+ (((k2 - k1) * n20 - f12 * k1 * n10) * exp(- k2 * t)) / (k2 - k1) +
+ (f12 * k1 * n10 * exp(- k1 * t)) / (k2 - k1)
+ )
+ }
+ } else {
+ model_function <- function(psi, id, xidep) {
+ t <- xidep[, "time"]
+ n10 <- psi[id, 1]
+ k1 <- psi[id, 2]
+ k2 <- psi[id, 3]
+ f12 <- psi[id, 4]
+ ifelse(xidep[, "name"] == parent_name,
+ n10 * exp(- k1 * t),
+ (((k2 - k1) * n20 - f12 * k1 * n10) * exp(- k2 * t)) / (k2 - k1) +
+ (f12 * k1 * n10 * exp(- k1 * t)) / (k2 - k1)
+ )
+ }
+ transform.par = c(0, 1, 1, 3)
+ }
+ }
+ if (identical(types, c("DFOP", "SFO"))) {
+ if (transformations == "mkin") {
+ model_function <- function(psi, id, xidep) {
+ t <- xidep[, "time"]
+ n10 <- psi[id, 1]
+ k2 <- exp(psi[id, 2])
+ f12 <- plogis(psi[id, 3])
+ l1 <- exp(psi[id, 4])
+ l2 <- exp(psi[id, 5])
+ g <- plogis(psi[id, 6])
+ ifelse(xidep[, "name"] == parent_name,
+ n10 * (g * exp(- l1 * t) + (1 - g) * exp(- l2 * t)),
+ ((f12 * g - f12) * l2 * n10 * exp(- l2 * t)) / (l2 - k2) -
+ (f12 * g * l1 * n10 * exp(- l1 * t)) / (l1 - k2) +
+ ((((l1 - k2) * l2 - k2 * l1 + k2^2) * n20 +
+ ((f12 * l1 + (f12 * g - f12) * k2) * l2 -
+ f12 * g * k2 * l1) * n10) * exp( - k2 * t)) /
+ ((l1 - k2) * l2 - k2 * l1 + k2^2)
+ )
+ }
+ } else {
+ model_function <- function(psi, id, xidep) {
+ t <- xidep[, "time"]
+ n10 <- psi[id, 1]
+ k2 <- psi[id, 2]
+ f12 <- psi[id, 3]
+ l1 <- psi[id, 4]
+ l2 <- psi[id, 5]
+ g <- psi[id, 6]
+ ifelse(xidep[, "name"] == parent_name,
+ n10 * (g * exp(- l1 * t) + (1 - g) * exp(- l2 * t)),
+ ((f12 * g - f12) * l2 * n10 * exp(- l2 * t)) / (l2 - k2) -
+ (f12 * g * l1 * n10 * exp(- l1 * t)) / (l1 - k2) +
+ ((((l1 - k2) * l2 - k2 * l1 + k2^2) * n20 +
+ ((f12 * l1 + (f12 * g - f12) * k2) * l2 -
+ f12 * g * k2 * l1) * n10) * exp( - k2 * t)) /
+ ((l1 - k2) * l2 - k2 * l1 + k2^2)
+ )
+ }
+ transform.par = c(0, 1, 3, 1, 1, 3)
+ }
+ }
+ }
+ }
+ }
+
+ if (is.function(model_function) & solution_type == "auto") {
+ solution_type = "analytical saemix"
+ } else {
+
+ if (solution_type == "auto")
+ solution_type <- object[[1]]$solution_type
+
+ model_function <- function(psi, id, xidep) {
+
+ uid <- unique(id)
+
+ res_list <- lapply(uid, function(i) {
+
+ transparms_optim <- as.numeric(psi[i, ]) # psi[i, ] is a dataframe when called in saemix.predict
+ names(transparms_optim) <- names(degparms_optim)
+
+ odeini_optim <- transparms_optim[odeini_optim_parm_names]
+ names(odeini_optim) <- gsub('_0$', '', odeini_optim_parm_names)
+
+ odeini <- c(odeini_optim, odeini_fixed)[names(mkin_model$diffs)]
+
+ ode_transparms_optim_names <- setdiff(names(transparms_optim), odeini_optim_parm_names)
+ odeparms_optim <- backtransform_odeparms(transparms_optim[ode_transparms_optim_names], mkin_model,
+ transform_rates = object[[1]]$transform_rates,
+ transform_fractions = object[[1]]$transform_fractions)
+ odeparms <- c(odeparms_optim, odeparms_fixed)
+
+ xidep_i <- subset(xidep, id == i)
+
+ if (solution_type == "analytical") {
+ out_values <- mkin_model$deg_func(xidep_i, odeini, odeparms)
+ } else {
+
+ i_time <- xidep_i$time
+ i_name <- xidep_i$name
+
+ out_wide <- mkinpredict(mkin_model,
+ odeparms = odeparms, odeini = odeini,
+ solution_type = solution_type,
+ outtimes = sort(unique(i_time)),
+ na_stop = FALSE
+ )
+
+ out_index <- cbind(as.character(i_time), as.character(i_name))
+ out_values <- out_wide[out_index]
+ }
+ return(out_values)
+ })
+ res <- unlist(res_list)
+ return(res)
+ }
+ }
+
+ error.model <- switch(object[[1]]$err_mod,
+ const = "constant",
+ tc = "combined",
+ obs = "constant")
+
+ if (object[[1]]$err_mod == "obs") {
+ warning("The error model 'obs' (variance by variable) can currently not be transferred to an saemix model")
+ }
+
+ error.init <- switch(object[[1]]$err_mod,
+ const = c(a = mean(sapply(object, function(x) x$errparms)), b = 1),
+ tc = c(a = mean(sapply(object, function(x) x$errparms[1])),
+ b = mean(sapply(object, function(x) x$errparms[2]))),
+ obs = c(a = mean(sapply(object, function(x) x$errparms)), b = 1))
+
+ degparms_psi0 <- degparms_optim
+ degparms_psi0[names(degparms_start)] <- degparms_start
+ psi0_matrix <- matrix(degparms_psi0, nrow = 1)
+ colnames(psi0_matrix) <- names(degparms_psi0)
+
+ res <- saemix::saemixModel(model_function,
+ psi0 = psi0_matrix,
+ "Mixed model generated from mmkin object",
+ transform.par = transform.par,
+ error.model = error.model,
+ verbose = verbose
+ )
+ attr(res, "mean_dp_start") <- degparms_optim
+ return(res)
+}
+
+#' @rdname saem
+#' @return An [saemix::SaemixData] object.
+#' @export
+saemix_data <- function(object, verbose = FALSE, ...) {
+ if (nrow(object) > 1) stop("Only row objects allowed")
+ ds_names <- colnames(object)
+
+ ds_list <- lapply(object, function(x) x$data[c("time", "variable", "observed")])
+ names(ds_list) <- ds_names
+ ds_saemix_all <- purrr::map_dfr(ds_list, function(x) x, .id = "ds")
+ ds_saemix <- data.frame(ds = ds_saemix_all$ds,
+ name = as.character(ds_saemix_all$variable),
+ time = ds_saemix_all$time,
+ value = ds_saemix_all$observed,
+ stringsAsFactors = FALSE)
+
+ res <- saemix::saemixData(ds_saemix,
+ name.group = "ds",
+ name.predictors = c("time", "name"),
+ name.response = "value",
+ verbose = verbose,
+ ...)
+ return(res)
+}
diff --git a/R/summary.saem.mmkin.R b/R/summary.saem.mmkin.R
new file mode 100644
index 00000000..e92c561c
--- /dev/null
+++ b/R/summary.saem.mmkin.R
@@ -0,0 +1,268 @@
+#' Summary method for class "saem.mmkin"
+#'
+#' Lists model equations, initial parameter values, optimised parameters
+#' for fixed effects (population), random effects (deviations from the
+#' population mean) and residual error model, as well as the resulting
+#' endpoints such as formation fractions and DT50 values. Optionally
+#' (default is FALSE), the data are listed in full.
+#'
+#' @param object an object of class [saem.mmkin]
+#' @param x an object of class [summary.saem.mmkin]
+#' @param data logical, indicating whether the full data should be included in
+#' the summary.
+#' @param verbose Should the summary be verbose?
+#' @param distimes logical, indicating whether DT50 and DT90 values should be
+#' included.
+#' @param digits Number of digits to use for printing
+#' @param \dots optional arguments passed to methods like \code{print}.
+#' @return The summary function returns a list based on the [saemix::SaemixObject]
+#' obtained in the fit, with at least the following additional components
+#' \item{saemixversion, mkinversion, Rversion}{The saemix, mkin and R versions used}
+#' \item{date.fit, date.summary}{The dates where the fit and the summary were
+#' produced}
+#' \item{diffs}{The differential equations used in the degradation model}
+#' \item{use_of_ff}{Was maximum or minimum use made of formation fractions}
+#' \item{data}{The data}
+#' \item{confint_trans}{Transformed parameters as used in the optimisation, with confidence intervals}
+#' \item{confint_back}{Backtransformed parameters, with confidence intervals if available}
+#' \item{confint_errmod}{Error model parameters with confidence intervals}
+#' \item{ff}{The estimated formation fractions derived from the fitted
+#' model.}
+#' \item{distimes}{The DT50 and DT90 values for each observed variable.}
+#' \item{SFORB}{If applicable, eigenvalues of SFORB components of the model.}
+#' The print method is called for its side effect, i.e. printing the summary.
+#' @importFrom stats predict vcov
+#' @author Johannes Ranke for the mkin specific parts
+#' saemix authors for the parts inherited from saemix.
+#' @examples
+#' # Generate five datasets following DFOP-SFO kinetics
+#' sampling_times = c(0, 1, 3, 7, 14, 28, 60, 90, 120)
+#' dfop_sfo <- mkinmod(parent = mkinsub("DFOP", "m1"),
+#' m1 = mkinsub("SFO"), quiet = TRUE)
+#' set.seed(1234)
+#' k1_in <- rlnorm(5, log(0.1), 0.3)
+#' k2_in <- rlnorm(5, log(0.02), 0.3)
+#' g_in <- plogis(rnorm(5, qlogis(0.5), 0.3))
+#' f_parent_to_m1_in <- plogis(rnorm(5, qlogis(0.3), 0.3))
+#' k_m1_in <- rlnorm(5, log(0.02), 0.3)
+#'
+#' pred_dfop_sfo <- function(k1, k2, g, f_parent_to_m1, k_m1) {
+#' mkinpredict(dfop_sfo,
+#' c(k1 = k1, k2 = k2, g = g, f_parent_to_m1 = f_parent_to_m1, k_m1 = k_m1),
+#' c(parent = 100, m1 = 0),
+#' sampling_times)
+#' }
+#'
+#' ds_mean_dfop_sfo <- lapply(1:5, function(i) {
+#' mkinpredict(dfop_sfo,
+#' c(k1 = k1_in[i], k2 = k2_in[i], g = g_in[i],
+#' f_parent_to_m1 = f_parent_to_m1_in[i], k_m1 = k_m1_in[i]),
+#' c(parent = 100, m1 = 0),
+#' sampling_times)
+#' })
+#' names(ds_mean_dfop_sfo) <- paste("ds", 1:5)
+#'
+#' ds_syn_dfop_sfo <- lapply(ds_mean_dfop_sfo, function(ds) {
+#' add_err(ds,
+#' sdfunc = function(value) sqrt(1^2 + value^2 * 0.07^2),
+#' n = 1)[[1]]
+#' })
+#'
+#' \dontrun{
+#' # Evaluate using mmkin and saem
+#' f_mmkin_dfop_sfo <- mmkin(list(dfop_sfo), ds_syn_dfop_sfo,
+#' quiet = TRUE, error_model = "tc", cores = 5)
+#' f_saem_dfop_sfo <- saem(f_mmkin_dfop_sfo)
+#' summary(f_saem_dfop_sfo, data = TRUE)
+#' }
+#'
+#' @export
+summary.saem.mmkin <- function(object, data = FALSE, verbose = FALSE, distimes = TRUE, ...) {
+
+ mod_vars <- names(object$mkinmod$diffs)
+
+ pnames <- names(object$mean_dp_start)
+ np <- length(pnames)
+
+ conf.int <- object$so@results@conf.int
+ rownames(conf.int) <- conf.int$name
+ confint_trans <- as.matrix(conf.int[pnames, c("estimate", "lower", "upper")])
+ colnames(confint_trans)[1] <- "est."
+
+ # In case objects were produced by earlier versions of saem
+ if (is.null(object$transformations)) object$transformations <- "mkin"
+
+ if (object$transformations == "mkin") {
+ bp <- backtransform_odeparms(confint_trans[, "est."], object$mkinmod,
+ object$transform_rates, object$transform_fractions)
+ bpnames <- names(bp)
+
+ # Transform boundaries of CI for one parameter at a time,
+ # with the exception of sets of formation fractions (single fractions are OK).
+ f_names_skip <- character(0)
+ for (box in mod_vars) { # Figure out sets of fractions to skip
+ f_names <- grep(paste("^f", box, sep = "_"), pnames, value = TRUE)
+ n_paths <- length(f_names)
+ if (n_paths > 1) f_names_skip <- c(f_names_skip, f_names)
+ }
+
+ confint_back <- matrix(NA, nrow = length(bp), ncol = 3,
+ dimnames = list(bpnames, colnames(confint_trans)))
+ confint_back[, "est."] <- bp
+
+ for (pname in pnames) {
+ if (!pname %in% f_names_skip) {
+ par.lower <- confint_trans[pname, "lower"]
+ par.upper <- confint_trans[pname, "upper"]
+ names(par.lower) <- names(par.upper) <- pname
+ bpl <- backtransform_odeparms(par.lower, object$mkinmod,
+ object$transform_rates,
+ object$transform_fractions)
+ bpu <- backtransform_odeparms(par.upper, object$mkinmod,
+ object$transform_rates,
+ object$transform_fractions)
+ confint_back[names(bpl), "lower"] <- bpl
+ confint_back[names(bpu), "upper"] <- bpu
+ }
+ }
+ } else {
+ confint_back <- confint_trans
+ }
+
+ # Correlation of fixed effects (inspired by summary.nlme)
+ varFix <- vcov(object$so)[1:np, 1:np]
+ stdFix <- sqrt(diag(varFix))
+ object$corFixed <- array(
+ t(varFix/stdFix)/stdFix,
+ dim(varFix),
+ list(pnames, pnames))
+
+ # Random effects
+ rnames <- paste0("SD.", pnames)
+ confint_ranef <- as.matrix(conf.int[rnames, c("estimate", "lower", "upper")])
+ colnames(confint_ranef)[1] <- "est."
+
+ # Error model
+ enames <- if (object$err_mod == "const") "a.1" else c("a.1", "b.1")
+ confint_errmod <- as.matrix(conf.int[enames, c("estimate", "lower", "upper")])
+ colnames(confint_errmod)[1] <- "est."
+
+
+ object$confint_trans <- confint_trans
+ object$confint_ranef <- confint_ranef
+ object$confint_errmod <- confint_errmod
+ object$confint_back <- confint_back
+
+ object$date.summary = date()
+ object$use_of_ff = object$mkinmod$use_of_ff
+ object$error_model_algorithm = object$mmkin_orig[[1]]$error_model_algorithm
+ err_mod = object$mmkin_orig[[1]]$err_mod
+
+ object$diffs <- object$mkinmod$diffs
+ object$print_data <- data # boolean: Should we print the data?
+ so_pred <- object$so@results@predictions
+
+ names(object$data)[4] <- "observed" # rename value to observed
+
+ object$verbose <- verbose
+
+ object$fixed <- object$mmkin_orig[[1]]$fixed
+ object$AIC = AIC(object$so)
+ object$BIC = BIC(object$so)
+ object$logLik = logLik(object$so, method = "is")
+
+ ep <- endpoints(object)
+ if (length(ep$ff) != 0)
+ object$ff <- ep$ff
+ if (distimes) object$distimes <- ep$distimes
+ if (length(ep$SFORB) != 0) object$SFORB <- ep$SFORB
+ class(object) <- c("summary.saem.mmkin")
+ return(object)
+}
+
+#' @rdname summary.saem.mmkin
+#' @export
+print.summary.saem.mmkin <- function(x, digits = max(3, getOption("digits") - 3), verbose = x$verbose, ...) {
+ cat("saemix version used for fitting: ", x$saemixversion, "\n")
+ cat("mkin version used for pre-fitting: ", x$mkinversion, "\n")
+ cat("R version used for fitting: ", x$Rversion, "\n")
+
+ cat("Date of fit: ", x$date.fit, "\n")
+ cat("Date of summary:", x$date.summary, "\n")
+
+ cat("\nEquations:\n")
+ nice_diffs <- gsub("^(d.*) =", "\\1/dt =", x[["diffs"]])
+ writeLines(strwrap(nice_diffs, exdent = 11))
+
+ cat("\nData:\n")
+ cat(nrow(x$data), "observations of",
+ length(unique(x$data$name)), "variable(s) grouped in",
+ length(unique(x$data$ds)), "datasets\n")
+
+ cat("\nModel predictions using solution type", x$solution_type, "\n")
+
+ cat("\nFitted in", x$time[["elapsed"]], "s using", paste(x$so@options$nbiter.saemix, collapse = ", "), "iterations\n")
+
+ cat("\nVariance model: ")
+ cat(switch(x$err_mod,
+ const = "Constant variance",
+ obs = "Variance unique to each observed variable",
+ tc = "Two-component variance function"), "\n")
+
+ cat("\nMean of starting values for individual parameters:\n")
+ print(x$mean_dp_start, digits = digits)
+
+ cat("\nFixed degradation parameter values:\n")
+ if(length(x$fixed$value) == 0) cat("None\n")
+ else print(x$fixed, digits = digits)
+
+ cat("\nResults:\n\n")
+ cat("Likelihood computed by importance sampling\n")
+ print(data.frame(AIC = x$AIC, BIC = x$BIC, logLik = x$logLik,
+ row.names = " "), digits = digits)
+
+ cat("\nOptimised parameters:\n")
+ print(x$confint_trans, digits = digits)
+
+ if (nrow(x$confint_trans) > 1) {
+ corr <- x$corFixed
+ class(corr) <- "correlation"
+ print(corr, title = "\nCorrelation:", ...)
+ }
+
+ cat("\nRandom effects:\n")
+ print(x$confint_ranef, digits = digits)
+
+ cat("\nVariance model:\n")
+ print(x$confint_errmod, digits = digits)
+
+ if (x$transformations == "mkin") {
+ cat("\nBacktransformed parameters:\n")
+ print(x$confint_back, digits = digits)
+ }
+
+ printSFORB <- !is.null(x$SFORB)
+ if(printSFORB){
+ cat("\nEstimated Eigenvalues of SFORB model(s):\n")
+ print(x$SFORB, digits = digits,...)
+ }
+
+ printff <- !is.null(x$ff)
+ if(printff){
+ cat("\nResulting formation fractions:\n")
+ print(data.frame(ff = x$ff), digits = digits,...)
+ }
+
+ printdistimes <- !is.null(x$distimes)
+ if(printdistimes){
+ cat("\nEstimated disappearance times:\n")
+ print(x$distimes, digits = digits,...)
+ }
+
+ if (x$print_data){
+ cat("\nData:\n")
+ print(format(x$data, digits = digits, ...), row.names = FALSE)
+ }
+
+ invisible(x)
+}

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