diff options
author | Johannes Ranke <jranke@uni-bremen.de> | 2020-06-04 13:27:44 +0200 |
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committer | Johannes Ranke <jranke@uni-bremen.de> | 2020-06-04 13:27:44 +0200 |
commit | ae64167d93bfae36158578f0a1c7771e6bab9350 (patch) | |
tree | a29ed6dc384956d6b35587c628f8ff035e09c327 /CakeSummary.R | |
parent | 1684a82b15dee35812c1340e26d721ee64a28751 (diff) |
Version 3.4 as just publicly announcedv3.4
Peter Rainbird just announced the release on the PFMODELS email list.
Diffstat (limited to 'CakeSummary.R')
-rw-r--r-- | CakeSummary.R | 37 |
1 files changed, 19 insertions, 18 deletions
diff --git a/CakeSummary.R b/CakeSummary.R index 70f01e6..5849a4a 100644 --- a/CakeSummary.R +++ b/CakeSummary.R @@ -3,8 +3,8 @@ # and display the summary itself. # Parts modified from package mkin -# Parts Tessella for Syngenta: Copyright (C) 2011-2016 Syngenta -# Tessella Project Reference: 6245, 7247, 8361, 7414 +# Parts Tessella for Syngenta: Copyright (C) 2011-2020 Syngenta +# Tessella Project Reference: 6245, 7247, 8361, 7414, 10091 # The CAKE R modules are free software: you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by @@ -100,8 +100,8 @@ CakeFOMCBackCalculatedDT<-function(parms.all) { # type - type of compartment # obs_var - compartment name # parms.all - list of parameters -# sannMaxIter - the maximum amount of iterations to do for SANN -CakeDT<-function(type, obs_var, parms.all, sannMaxIter) { +# dfopDtMaxIter - the maximum amount of iterations to do for DFOP DT calculation +CakeDT<-function(type, obs_var, parms.all, dfopDtMaxIter) { if (type == "SFO") { k_name = paste("k", obs_var, sep="_") k_tot = parms.all[k_name] @@ -122,21 +122,19 @@ CakeDT<-function(type, obs_var, parms.all, sannMaxIter) { fraction <- g * exp( - k1 * t) + (1 - g) * exp( - k2 * t) (fraction - (1 - x/100))^2 } - - DTminBounds <- 0.001 - # Determine a decent starting point for numerical iteration. The latter two terms are also lower bounds for DT50. - DT50min <- max(0.001, (1 / k1) * log(g * 2), (1 / k2) * log((1 - g) * 2)) + # Determine a decent starting point for numerical iteration. These are lower bounds for DT50. + DT50min <- max((1 / k1) * log(g * 2), (1 / k2) * log((1 - g) * 2)) - # Set the starting point for the numerical solver to a be a bit smaller than the computed minimum as the R optim function seems to get confused if the min is - # greater than the answer it's trying to converge to (up to its level of accuracy). + # Set the starting point for the numerical solver to a be a bit smaller than the computed minimum. DT50Initial <- DT50min * 0.9 # Results greater than 10,000 are not interesting. The R optim routine also handles very large values unreliably and can claim to converge when it is nowhere near. if (DT50min > 10000){ DT50 = ">10,000" }else{ - DT50.temp <- optim(DT50Initial, f, method="SANN", control=list(fnscale=0.05, maxit=sannMaxIter), x = 50, lower = DTminBounds) + DT50.temp <- optim(DT50Initial, f, method="Nelder-Mead", control=list(maxit=dfopDtMaxIter, abstol=1E-10), x = 50) + DT50.o = DT50.temp$par DT50.converged = DT50.temp$convergence == 0 DT50 = ifelse(!DT50.converged || DT50.o <= 0, NA, DT50.o) @@ -146,17 +144,16 @@ CakeDT<-function(type, obs_var, parms.all, sannMaxIter) { } } - # Determine a decent starting point for numerical iteration. The latter two terms are also lower bounds for DT90. - DT90min <- max(0.001, (1 / k1) * log(g * 10), (1 / k2) * log((1 - g) * 10)) + # Determine a decent starting point for numerical iteration. These are lower bounds for DT90. + DT90min <- max((1 / k1) * log(g * 10), (1 / k2) * log((1 - g) * 10)) - # Set the starting point for the numerical solver to a be a bit smaller than the computed minimum as the R optim function seems to get confused if the min is - # greater than the answer it's trying to converge to (up to its level of accuracy). + # Set the starting point for the numerical solver to a be a bit smaller than the computed minimum. DT90Initial <- DT90min * 0.9 if (DT90min > 10000){ DT90 = ">10,000" }else{ - DT90.temp <- optim(DT90Initial, f, method="SANN", control=list(fnscale=0.05, maxit=sannMaxIter), x = 90, lower = DTminBounds) + DT90.temp <- optim(DT90Initial, f, method="Nelder-Mead", control=list(maxit=dfopDtMaxIter, abstol=1E-10), x = 90) DT90.o = DT90.temp$par DT90.converged = DT90.temp$convergence == 0 DT90 = ifelse(!DT90.converged || DT90.o <= 0, NA, DT90.o) @@ -321,7 +318,8 @@ summary.CakeFit <- function(object, data = TRUE, distimes = TRUE, halflives = TR dimnames(param) <- list(pnames, c("Estimate", "Std. Error", "t value", "Pr(>t)", "Lower CI (90%)", "Upper CI (90%)", "Lower CI (95%)", "Upper CI (95%)")) - ans <- list(residuals = object$residuals, + ans <- list(ssr = object$ssr, + residuals = object$residuals, residualVariance = resvar, sigma = sqrt(resvar), modVariance = modVariance, @@ -332,7 +330,8 @@ summary.CakeFit <- function(object, data = TRUE, distimes = TRUE, halflives = TR par = param) } else { param <- cbind(param) - ans <- list(residuals = object$residuals, + ans <- list(ssr = object$ssr, + residuals = object$residuals, residualVariance = resvar, sigma = sqrt(resvar), modVariance = modVariance, @@ -382,6 +381,8 @@ print.summary.CakeFit <- function(x, digits = max(3, getOption("digits") - 3), . cat("\nOptimised parameters:\n") printCoefmat(x$par, digits = digits, ...) } + + cat("\nSum of squared residuals:", format(signif(x$ssr, digits))) cat("\nResidual standard error:", format(signif(x$sigma, digits)), "on", rdf, "degrees of freedom\n") |