Nothing
evalModels <- function(fits, groups, x){
# Invoke model evaluation
modelMetrics <- assessModelMetrics(fits = fits, x = x, groups = groups)
modelPredictions <- augmentModels(fits = fits, groups = groups)
return(list(modelMetrics = modelMetrics, modelPredictions = modelPredictions))
}
augmentModels <- function(fits, groups){
# Augment model to obtain data frame with measurements, predictions and residuals.
# ---- Computing model predictions and residuals ----
message("Computing model predictions and residuals ...")
modelPredictions <- fits %>%
filter(.data$successfulFit) %>%
group_by_at(c("iter", "id", groups)) %>%
do(augment(.data$fittedModel[[1]])) %>%
ungroup %>%
right_join(fits %>% select(!!c("iter", "id", groups)), by = c("iter", "id", groups)) %>% # fill for unsuccessful fits
select(-.data$iter)
message("... complete.\n")
return(modelPredictions)
}
assessModelMetrics <- function(fits, x, groups){
# Invoke calculation of performance metrics per model
message("Evaluating models ...")
metrics <- fits %>%
group_by_at(c("iter", "id", groups)) %>%
do(assessSingleModel(nls_obj = .data$fittedModel[[1]],
xVec = unique(x))) %>%
ungroup %>%
select(-.data$iter)
message("... complete.\n")
return(metrics)
}
#' @importFrom methods is
assessSingleModel <- function(nls_obj, xVec){
if (any(is.na(xVec))){
stop("Temperature vector contains missing values. Cannot integrate over these values to compute the curve area.")
}
tm = a = b = pl = aumc = tm_sd = rss = logL = nCoeffs = nFitted = resid_sd <- NA
conv <- FALSE
if (!is(nls_obj, "try-error")){
#meltCurve <- Reduce(paste, deparse(formula(nls_obj))) %>% gsub("y ~ ", "", .)
pars <- coefficients(nls_obj)
nCoeffs <- length(pars)
a <- pars[["a"]]
b <- pars[["b"]]
pl <- pars[["Pl"]]
yVec <- fitted(nls_obj) + resid(nls_obj)
tm_fct <- parse(text = "a / (b - log((1-pl)/(1/2 - pl) - 1))")
suppressWarnings(tm <- eval(tm_fct))
dtm_da <-D(tm_fct, "a")
dtm_db <-D(tm_fct, "b")
dtm_dpl <-D(tm_fct, "pl")
suppressWarnings(grad_tm <- c(a = eval(dtm_da), b = eval(dtm_db), pl = eval(dtm_dpl))) # derivatives of 'tm' .w.r.t. 'a' and 'b'
covmat <- try(vcov(nls_obj), silent = TRUE) # var-covar matrix of estimators 'a' and 'b'
if (!inherits(covmat, "try-error")){
var_tm <- grad_tm %*% covmat[c("a", "b", "Pl"), c("a", "b", "Pl")] %*% grad_tm
tm_sd <- as.numeric(sqrt(var_tm)) # squash matrix to vector
}
## Compute area under the melting curve:
int <- try(integrate(function(x,m) predict(m, newdata = list(x=x)),
min(xVec), max(xVec), nls_obj), silent = TRUE)
if (!inherits(int, "try-error")){
aumc <- int$value
}
nFitted <- nobs(nls_obj)
rss <- sum(resid(nls_obj)^2, na.rm = TRUE)
resid_sd <- sqrt(rss/nFitted)
logL <- -nFitted/2 * log(2*pi*resid_sd^2) - rss/(2*resid_sd^2) #loglik <- logLik(m)
nonNAs <- sum(!is.na(resid(nls_obj)))
conv <- nls_obj$convInfo$isConv
}
return(data.frame(tm = tm, a = a, b = b, pl = pl, aumc = aumc,
resid_sd = resid_sd, rss = rss, loglik = logL,
tm_sd = tm_sd, nCoeffs = nCoeffs, nFitted = nFitted, conv = conv))
}
Any scripts or data that you put into this service are public.
Add the following code to your website.
For more information on customizing the embed code, read Embedding Snippets.