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-rw-r--r--R/mkinfit.R229
-rw-r--r--R/predict.mkinmod.R89
-rw-r--r--R/transform_odeparms.R46
3 files changed, 180 insertions, 184 deletions
diff --git a/R/mkinfit.R b/R/mkinfit.R
index 83896bce..47c39cf2 100644
--- a/R/mkinfit.R
+++ b/R/mkinfit.R
@@ -32,9 +32,12 @@ mkinfit <- function(mkinmod, observed,
atol = 1e-6,
...)
{
+ # Get the names of the state variables in the model
mod_vars <- names(mkinmod$diffs)
- # Subset dataframe of observed variables with mapped (modelled) variables
+
+ # Subset observed data with names of observed data in the model
observed <- subset(observed, name %in% names(mkinmod$map))
+
# Get names of observed variables
obs_vars = unique(as.character(observed$name))
@@ -42,26 +45,33 @@ mkinfit <- function(mkinmod, observed,
if (parms.ini[[1]] == "auto") parms.ini = vector()
defaultpar.names <- setdiff(mkinmod$parms, names(parms.ini))
for (parmname in defaultpar.names) {
- # Default values for the FOMC model
+ # Default values for rate constants, depending on the parameterisation
+ if (substr(parmname, 1, 2) == "k_") parms.ini[parmname] = 0.1
+ # Default values for formation fractions
+ if (substr(parmname, 1, 2) == "f_") parms.ini[parmname] = 0.1
+ # Default values for the FOMC, DFOP and HS models
if (parmname == "alpha") parms.ini[parmname] = 1
if (parmname == "beta") parms.ini[parmname] = 10
- # Default values for log of rate constants, depending on the parameterisation
- if (substr(parmname, 1, 2) == "k_") parms.ini[parmname] = -2.3
- # Default values for ilr of formation fractions
- if (substr(parmname, 1, 2) == "f_") parms.ini[parmname] = 0.1
+ if (parmname == "k1") parms.ini[parmname] = 0.1
+ if (parmname == "k2") parms.ini[parmname] = 0.01
+ if (parmname == "tb") parms.ini[parmname] = 5
+ if (parmname == "g") parms.ini[parmname] = 0.5
}
+ parms.ini <- transform_odeparms(parms.ini, mod_vars)
- # Name the inital parameter values if they are not named yet
+ # Name the inital state variable values if they are not named yet
if(is.null(names(state.ini))) names(state.ini) <- mod_vars
- # Parameters to be optimised
+ # Parameters to be optimised:
+ # Kinetic parameters in parms.ini whose names are not in fixed_parms
parms.fixed <- parms.ini[fixed_parms]
- optim_parms <- setdiff(names(parms.ini), fixed_parms)
- parms.optim <- parms.ini[optim_parms]
+ parms.optim <- parms.ini[setdiff(names(parms.ini), fixed_parms)]
+ # Inital state variables in state.ini whose names are not in fixed_initials
state.ini.fixed <- state.ini[fixed_initials]
- optim_initials <- setdiff(names(state.ini), fixed_initials)
- state.ini.optim <- state.ini[optim_initials]
+ state.ini.optim <- state.ini[setdiff(names(state.ini), fixed_initials)]
+
+ # Preserve names of state variables before renaming initial state variable parameters
state.ini.optim.boxnames <- names(state.ini.optim)
if(length(state.ini.optim) > 0) {
names(state.ini.optim) <- paste(names(state.ini.optim), "0", sep="_")
@@ -77,42 +87,17 @@ mkinfit <- function(mkinmod, observed,
else solution = "deSolve"
}
- # Create a function calculating the differentials specified by the model
- # if necessary
- if(solution == "deSolve") {
- mkindiff <- function(t, state, parms) {
- transparms <- vector()
- transparms <- c(transparms, exp(parms[grep("^k_", names(parms))]))
- for (box in mod_vars) {
- path_indices <- grep(paste("^f", box, sep = "_"), names(parms))
- n_paths <- length(path_indices)
- if (n_paths > 0) {
- f <- invilr(parms[grep(paste("^f", box, sep="_"), names(parms))])
- transparms <- c(transparms, f[1:n_paths])
- }
- }
- otherparms <- parms[setdiff(names(parms), names(transparms))]
- parms <- c(transparms, otherparms)
-
- time <- t
- diffs <- vector()
- for (box in mod_vars)
- {
- diffname <- paste("d", box, sep="_")
- diffs[diffname] <- with(as.list(c(time, state, parms)),
- eval(parse(text=mkinmod$diffs[[box]])))
- }
- return(list(c(diffs)))
- }
- }
-
- cost.old <- 1e100
- calls <- 0
+ cost.old <- 1e100 # The first model cost should be smaller than this value
+ calls <- 0 # Counter for number of model solutions
out_predicted <- NA
# Define the model cost function
cost <- function(P)
{
- assign("calls", calls+1, inherits=TRUE)
+ assign("calls", calls+1, inherits=TRUE) # Increase the model solution counter
+
+ # Time points at which observed data are available
+ outtimes = unique(observed$time)
+
if(length(state.ini.optim) > 0) {
odeini <- c(P[1:length(state.ini.optim)], state.ini.fixed)
names(odeini) <- c(state.ini.optim.boxnames, names(state.ini.fixed))
@@ -120,76 +105,14 @@ mkinfit <- function(mkinmod, observed,
odeparms <- c(P[(length(state.ini.optim) + 1):length(P)], parms.fixed)
- outtimes = unique(observed$time)
- evalparse <- function(string)
- {
- eval(parse(text=string), as.list(c(odeparms, odeini)))
- }
+ transparms <- transform_odeparms(odeparms, mod_vars)
- # Solve the system
- if (solution == "analytical") {
- parent.type = names(mkinmod$map[[1]])[1]
- parent.name = names(mkinmod$diffs)[[1]]
- o <- switch(parent.type,
- SFO = SFO.solution(outtimes,
- evalparse(parent.name),
- evalparse(paste("k", parent.name, "sink", sep="_"))),
- FOMC = FOMC.solution(outtimes,
- evalparse(parent.name),
- evalparse("alpha"), evalparse("beta")),
- DFOP = DFOP.solution(outtimes,
- evalparse(parent.name),
- evalparse("k1"), evalparse("k2"),
- evalparse("g")),
- HS = HS.solution(outtimes,
- evalparse(parent.name),
- evalparse("k1"), evalparse("k2"),
- evalparse("tb")),
- SFORB = SFORB.solution(outtimes,
- evalparse(parent.name),
- evalparse(paste("k", parent.name, "bound", sep="_")),
- evalparse(paste("k", sub("free", "bound", parent.name), "free", sep="_")),
- evalparse(paste("k", parent.name, "sink", sep="_")))
- )
- out <- cbind(outtimes, o)
- dimnames(out) <- list(outtimes, c("time", sub("_free", "", parent.name)))
- }
- if (solution == "eigen") {
- coefmat.num <- matrix(sapply(as.vector(mkinmod$coefmat), evalparse),
- nrow = length(mod_vars))
- e <- eigen(coefmat.num)
- c <- solve(e$vectors, odeini)
- f.out <- function(t) {
- e$vectors %*% diag(exp(e$values * t), nrow=length(mod_vars)) %*% c
- }
- o <- matrix(mapply(f.out, outtimes),
- nrow = length(mod_vars), ncol = length(outtimes))
- dimnames(o) <- list(mod_vars, outtimes)
- out <- cbind(time = outtimes, t(o))
- }
- if (solution == "deSolve")
- {
- out <- ode(
- y = odeini,
- times = outtimes,
- func = mkindiff,
- parms = odeparms,
- atol = atol
- )
- }
-
- # Output transformation for models with unobserved compartments like SFORB
- out_transformed <- data.frame(time = out[,"time"])
- for (var in names(mkinmod$map)) {
- if((length(mkinmod$map[[var]]) == 1) || solution == "analytical") {
- out_transformed[var] <- out[, var]
- } else {
- out_transformed[var] <- rowSums(out[, mkinmod$map[[var]]])
- }
- }
- assign("out_predicted", out_transformed, inherits=TRUE)
+ # Solve the system with current transformed parameter values
+ out <- predict(mkinmod, transparms, odeini, outtimes, solution_type = solution)
+
+ assign("out_predicted", out, inherits=TRUE)
- mC <- modCost(out_transformed, observed, y = "value",
+ mC <- modCost(out, observed, y = "value",
err = err, weight = weight, scaleVar = scaleVar)
# Report and/or plot if the model is improved
@@ -199,53 +122,9 @@ mkinfit <- function(mkinmod, observed,
# Plot the data and current model output if requested
if(plot) {
outtimes_plot = seq(min(observed$time), max(observed$time), length.out=100)
- if (solution == "analytical") {
- o_plot <- switch(parent.type,
- SFO = SFO.solution(outtimes_plot,
- evalparse(parent.name),
- evalparse(paste("k", parent.name, "sink", sep="_"))),
- FOMC = FOMC.solution(outtimes_plot,
- evalparse(parent.name),
- evalparse("alpha"), evalparse("beta")),
- DFOP = DFOP.solution(outtimes_plot,
- evalparse(parent.name),
- evalparse("k1"), evalparse("k2"),
- evalparse("g")),
- HS = HS.solution(outtimes_plot,
- evalparse(parent.name),
- evalparse("k1"), evalparse("k2"),
- evalparse("tb")),
- SFORB = SFORB.solution(outtimes_plot,
- evalparse(parent.name),
- evalparse(paste("k", parent.name, "bound", sep="_")),
- evalparse(paste("k", sub("free", "bound", parent.name), "free", sep="_")),
- evalparse(paste("k", parent.name, "sink", sep="_")))
- )
- out_plot <- cbind(outtimes_plot, o_plot)
- dimnames(out_plot) <- list(outtimes_plot, c("time", sub("_free", "", parent.name)))
- }
- if(solution == "eigen") {
- o_plot <- matrix(mapply(f.out, outtimes_plot),
- nrow = length(mod_vars), ncol = length(outtimes_plot))
- dimnames(o_plot) <- list(mod_vars, outtimes_plot)
- out_plot <- cbind(time = outtimes_plot, t(o_plot))
- }
- if (solution == "deSolve") {
- out_plot <- ode(
- y = odeini,
- times = outtimes_plot,
- func = mkindiff,
- parms = odeparms)
- }
- out_transformed_plot <- data.frame(time = out_plot[,"time"])
- for (var in obs_vars) {
- if((length(mkinmod$map[[var]]) == 1) || solution == "analytical") {
- out_transformed_plot[var] <- out_plot[, var]
- } else {
- out_transformed_plot[var] <- rowSums(out_plot[, mkinmod$map[[var]]])
- }
- }
- out_transformed_plot <<- out_transformed_plot
+
+ out_plot <- predict(mkinmod, transparms, odeini, outtimes_plot,
+ solution_type = solution)
plot(0, type="n",
xlim = range(observed$time), ylim = range(observed$value, na.rm=TRUE),
@@ -256,7 +135,7 @@ mkinfit <- function(mkinmod, observed,
points(subset(observed, name == obs_var, c(time, value)),
pch = pch_obs[obs_var], col = col_obs[obs_var])
}
- matlines(out_transformed_plot$time, out_transformed_plot[-1])
+ matlines(out_plot$time, out_plot[-1])
legend("topright", inset=c(0.05, 0.05), legend=obs_vars,
col=col_obs, pch=pch_obs, lty=1:length(pch_obs))
}
@@ -272,12 +151,6 @@ mkinfit <- function(mkinmod, observed,
if (solution == "eigen") {
fit$coefmat <- mkinmod$coefmat
}
- if (solution == "deSolve") {
- fit$mkindiff <- mkindiff
- }
- if (plot == TRUE) {
- fit$out_transformed_plot = out_transformed_plot
- }
# We also need various other information for summary and plotting
fit$map <- mkinmod$map
@@ -289,8 +162,6 @@ mkinfit <- function(mkinmod, observed,
# Collect initial parameter values in two dataframes
fit$start <- data.frame(initial = c(state.ini.optim, parms.optim))
fit$start$type = c(rep("state", length(state.ini.optim)), rep("deparm", length(parms.optim)))
- fit$start$lower <- lower
- fit$start$upper <- upper
fit$fixed <- data.frame(
value = c(state.ini.fixed, parms.fixed))
@@ -322,11 +193,10 @@ mkinfit <- function(mkinmod, observed,
}
fit$errmin <- errmin
- # Calculate dissipation times DT50 and DT90 and formation fractions
- parms.all = c(fit$par, parms.fixed)
+ # Calculate dissipation times DT50 and DT90 from parameters
+ parms.all = transform_odeparms(c(fit$par, parms.fixed), mod_vars)
fit$distimes <- data.frame(DT50 = rep(NA, length(obs_vars)), DT90 = rep(NA, length(obs_vars)),
row.names = obs_vars)
- fit$ff <- vector()
fit$SFORB <- vector()
for (obs_var in obs_vars) {
type = names(mkinmod$map[[obs_var]])[1]
@@ -374,16 +244,6 @@ mkinfit <- function(mkinmod, observed,
DT50 <- DTx(50)
DT90 <- DTx(90)
}
- # Back-calculation of formation fractions in case of nonlinear parent kinetics
- if (type %in% c("FOMC", "DFOP", "HS")) {
- ff_names = names(mkinmod$ff)
- for (ff_name in ff_names)
- {
- fit$ff[[paste(obs_var, ff_name, sep="_")]] =
- eval(parse(text = mkinmod$ff[ff_name]), as.list(parms.all))
- }
- fit$ff[[paste(obs_var, "sink", sep="_")]] = 1 - sum(fit$ff)
- }
if (type == "SFORB") {
# FOCUS kinetics (2006), p. 60 f
k_out_names = grep(paste("k", obs_var, "free", sep="_"), names(parms.all), value=TRUE)
@@ -474,9 +334,10 @@ summary.mkinfit <- function(object, data = TRUE, distimes = TRUE, ff = TRUE, ...
ans$diffs <- object$diffs
if(data) ans$data <- object$data
ans$start <- object$start
- if (object$logk) {
- names(ans$start) <- sub("^k_", "log k_", names(ans$start))
- }
+
+ # Fix names of parameters to show that they were transformed
+ names(ans$start) <- sub("^k_", "log k_", names(ans$start))
+
ans$fixed <- object$fixed
ans$errmin <- object$errmin
if(distimes) ans$distimes <- object$distimes
diff --git a/R/predict.mkinmod.R b/R/predict.mkinmod.R
new file mode 100644
index 00000000..279fa525
--- /dev/null
+++ b/R/predict.mkinmod.R
@@ -0,0 +1,89 @@
+predict.mkinmod <- function(mkinmod, odeparms, odeini, outtimes, solution_type = "deSolve", map_output = TRUE, atol = 1e-6) {
+
+ # Get the names of the state variables in the model
+ mod_vars <- names(mkinmod$diffs)
+
+ # Create function for evaluation of expressions with ode parameters and initial values
+ evalparse <- function(string)
+ {
+ eval(parse(text=string), as.list(c(odeparms, odeini)))
+ }
+
+ # Create a function calculating the differentials specified by the model
+ # if necessary
+ if (solution_type == "analytical") {
+ parent.type = names(mkinmod$map[[1]])[1]
+ parent.name = names(mkinmod$diffs)[[1]]
+ o <- switch(parent.type,
+ SFO = SFO.solution(outtimes,
+ evalparse(parent.name),
+ evalparse(paste("k", parent.name, sep="_"))),
+ FOMC = FOMC.solution(outtimes,
+ evalparse(parent.name),
+ evalparse("alpha"), evalparse("beta")),
+ DFOP = DFOP.solution(outtimes,
+ evalparse(parent.name),
+ evalparse("k1"), evalparse("k2"),
+ evalparse("g")),
+ HS = HS.solution(outtimes,
+ evalparse(parent.name),
+ evalparse("k1"), evalparse("k2"),
+ evalparse("tb")),
+ SFORB = SFORB.solution(outtimes,
+ evalparse(parent.name),
+ evalparse(paste("k", parent.name, "bound", sep="_")),
+ evalparse(paste("k", sub("free", "bound", parent.name), "free", sep="_")),
+ evalparse(paste("k", parent.name, sep="_")))
+ )
+ out <- cbind(outtimes, o)
+ dimnames(out) <- list(outtimes, c("time", sub("_free", "", parent.name)))
+ }
+ if (solution_type == "eigen") {
+ coefmat.num <- matrix(sapply(as.vector(mkinmod$coefmat), evalparse),
+ nrow = length(mod_vars))
+ e <- eigen(coefmat.num)
+ c <- solve(e$vectors, odeini)
+ f.out <- function(t) {
+ e$vectors %*% diag(exp(e$values * t), nrow=length(mod_vars)) %*% c
+ }
+ o <- matrix(mapply(f.out, outtimes),
+ nrow = length(mod_vars), ncol = length(outtimes))
+ dimnames(o) <- list(mod_vars, outtimes)
+ out <- cbind(time = outtimes, t(o))
+ }
+ if (solution_type == "deSolve") {
+ mkindiff <- function(t, state, parms) {
+
+ time <- t
+ diffs <- vector()
+ for (box in names(mkinmod$diffs))
+ {
+ diffname <- paste("d", box, sep="_")
+ diffs[diffname] <- with(as.list(c(time, state, parms)),
+ eval(parse(text=mkinmod$diffs[[box]])))
+ }
+ return(list(c(diffs)))
+ }
+ out <- ode(
+ y = odeini,
+ times = outtimes,
+ func = mkindiff,
+ parms = odeparms,
+ atol = atol
+ )
+ }
+ if (map_output) {
+ # Output transformation for models with unobserved compartments like SFORB
+ out_mapped <- data.frame(time = out[,"time"])
+ for (var in names(mkinmod$map)) {
+ if((length(mkinmod$map[[var]]) == 1) || solution == "analytical") {
+ out_mapped[var] <- out[, var]
+ } else {
+ out_mapped[var] <- rowSums(out[, mkinmod$map[[var]]])
+ }
+ }
+ return(out_mapped)
+ } else {
+ return(out)
+ }
+}
diff --git a/R/transform_odeparms.R b/R/transform_odeparms.R
new file mode 100644
index 00000000..4b8bfd14
--- /dev/null
+++ b/R/transform_odeparms.R
@@ -0,0 +1,46 @@
+transform_odeparms <- function(odeparms, mod_vars) {
+ # Transform rate constants and formation fractions
+ transparms <- odeparms
+ # Exponential transformation for rate constants
+ index_k <- grep("^k_", names(odeparms))
+ if (length(index_k) > 0) {
+ transparms[index_k] <- exp(odeparms[index_k])
+ }
+
+ # Go through state variables and apply inverse isotropic logratio transformation
+ for (box in mod_vars) {
+ indices_f <- grep(paste("^f", box, sep = "_"), names(odeparms))
+ f_names <- grep(paste("^f", box, sep = "_"), names(odeparms), value = TRUE)
+ n_paths <- length(indices_f)
+ if (n_paths > 0) {
+ f <- invilr(odeparms[indices_f])[1:n_paths] # We do not need the last component
+ names(f) <- f_names
+ transparms[indices_f] <- f
+ }
+ }
+ return(transparms)
+}
+
+backtransform_odeparms <- function(transparms, mod_vars) {
+ # Transform rate constants and formation fractions
+ odeparms <- transparms
+ # Log transformation for rate constants
+ index_k <- grep("^k_", names(transparms))
+ if (length(index_k) > 0) {
+ odeparms[index_k] <- log(transparms[index_k])
+ }
+
+ # Go through state variables and apply isotropic logratio transformation
+ for (box in mod_vars) {
+ indices_f <- grep(paste("^f", box, sep = "_"), names(transparms))
+ f_names <- grep(paste("^f", box, sep = "_"), names(transparms), value = TRUE)
+ n_paths <- length(indices_f)
+ if (n_paths > 0) {
+ trans_f <- transparms[indices_f]
+ f <- ilr(c(trans_f, 1 - sum(trans_f)))
+ names(f) <- f_names
+ odeparms[indices_f] <- f
+ }
+ }
+ return(odeparms)
+}

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