R/dcm.R
In statnet/EpiModel: Mathematical Modeling of Infectious Disease Dynamics
Defines functions
dcm
Documented in
dcm
#' @title Deterministic Compartmental Models
#'
#' @description Solves deterministic compartmental epidemic models for
#' infectious disease.
#'
#' @param param Model parameters, as an object of class \code{\link{param.dcm}}.
#' @param init Initial conditions, as an object of class \code{\link{init.dcm}}.
#' @param control Control settings, as an object of class
#' \code{\link{control.dcm}}.
#'
#' @details
#' The \code{dcm} function uses the ordinary differential equation solver in
#' the \code{deSolve} package to model disease as a deterministic compartmental
#' system. The parameterization for these models follows the standard approach
#' in \code{EpiModel}, with epidemic parameters, initial conditions, and control
#' settings. A description of solving DCMs with the \code{dcm} function may be
#' found in the \href{http://www.epimodel.org/tut.html}{Basic DCMs} tutorial.
#'
#' The \code{dcm} function performs modeling of both base model types and
#' original models with new structures. Base model types include one-group
#' and two-group models with disease types for Susceptible-Infected (SI),
#' Susceptible-Infected-Recovered (SIR), and Susceptible-Infected-Susceptible
#' (SIS). New model types may be written and input into \code{dcm} following the
#' steps outlined in the \href{http://www.epimodel.org/tut.html}{New DCMs}
#' tutorial. Both base and original models require the \code{param},
#' \code{init}, and \code{control} inputs.
#'
#' @return
#' A list of class \code{dcm} with the following elements:
#' \itemize{
#' \item \strong{param:} the epidemic parameters passed into the model through
#' \code{param}, with additional parameters added as necessary.
#' \item \strong{control:} the control settings passed into the model through
#' \code{control}, with additional controls added as necessary.
#' \item \strong{epi:} a list of data frames, one for each epidemiological
#' output from the model. Outputs for base models always include the
#' size of each compartment, as well as flows in, out of, and between
#' compartments.
#' }
#'
#' @references
#' Soetaert K, Petzoldt T, Setzer W. Solving Differential Equations in
#' R: Package deSolve. Journal of Statistical Software. 2010; 33(9): 1-25.
#' \doi{10.18637/jss.v033.i09}.
#'
#' @keywords model
#'
#' @seealso Extract the model results with \code{\link{as.data.frame.dcm}}.
#' Summarize the time-specific model results with \code{\link{summary.dcm}}.
#' Plot the model results with \code{\link{plot.dcm}}. Plot a compartment flow
#' diagram with \code{\link{comp_plot}}.
#'
#' @export
#'
#' @examples
#' ## Example 1: SI Model (One-Group)
#' # Set parameters
#' param <- param.dcm(inf.prob = 0.2, act.rate = 0.25)
#' init <- init.dcm(s.num = 500, i.num = 1)
#' control <- control.dcm(type = "SI", nsteps = 500)
#' mod1 <- dcm(param, init, control)
#' mod1
#' plot(mod1)
#'
#' ## Example 2: SIR Model with Vital Dynamics (One-Group)
#' param <- param.dcm(inf.prob = 0.2, act.rate = 5,
#' rec.rate = 1/3, a.rate = 1/90, ds.rate = 1/100,
#' di.rate = 1/35, dr.rate = 1/100)
#' init <- init.dcm(s.num = 500, i.num = 1, r.num = 0)
#' control <- control.dcm(type = "SIR", nsteps = 500)
#' mod2 <- dcm(param, init, control)
#' mod2
#' plot(mod2)
#'
#' ## Example 3: SIS Model with act.rate Sensitivity Parameter
#' param <- param.dcm(inf.prob = 0.2, act.rate = seq(0.1, 0.5, 0.1),
#' rec.rate = 1/50)
#' init <- init.dcm(s.num = 500, i.num = 1)
#' control <- control.dcm(type = "SIS", nsteps = 500)
#' mod3 <- dcm(param, init, control)
#' mod3
#' plot(mod3)
#'
#' ## Example 4: SI Model with Vital Dynamics (Two-Group)
#' param <- param.dcm(inf.prob = 0.4, inf.prob.g2 = 0.1,
#' act.rate = 0.25, balance = "g1",
#' a.rate = 1/100, a.rate.g2 = NA,
#' ds.rate = 1/100, ds.rate.g2 = 1/100,
#' di.rate = 1/50, di.rate.g2 = 1/50)
#' init <- init.dcm(s.num = 500, i.num = 1,
#' s.num.g2 = 500, i.num.g2 = 0)
#' control <- control.dcm(type = "SI", nsteps = 500)
#' mod4 <- dcm(param, init, control)
#' mod4
#' plot(mod4)
#'
dcm <- function(param, init, control) {
check.control.class("dcm", "EpiModel dcm")
crosscheck.dcm(param, init, control)
# Model selection ---------------------------------------------------------
if (is.null(control$new.mod)) {
if (control$type == "SI") {
if (param$groups == 1) {
if (param$vital == FALSE) {
model <- mod_SI_1g_cl
init <- c(init, si.flow = 0)
} else {
model <- mod_SI_1g_op
init <- c(init, si.flow = 0, a.flow = 0, ds.flow = 0, di.flow = 0)
}
} else {
if (param$vital == FALSE) {
model <- mod_SI_2g_cl
init <- c(init, si.flow = 0, si.flow.g2 = 0)
} else {
model <- mod_SI_2g_op
init <- c(init,
si.flow = 0, a.flow = 0, ds.flow = 0, di.flow = 0,
si.flow.g2 = 0, a.flow.g2 = 0, ds.flow.g2 = 0,
di.flow.g2 = 0)
}
}
}
if (control$type == "SIR") {
if (param$groups == 1) {
if (param$vital == FALSE) {
model <- mod_SIR_1g_cl
init <- c(init, si.flow = 0, ir.flow = 0)
} else {
model <- mod_SIR_1g_op
init <- c(init, si.flow = 0, ir.flow = 0, a.flow = 0,
ds.flow = 0, di.flow = 0, dr.flow = 0)
}
} else {
if (param$vital == FALSE) {
model <- mod_SIR_2g_cl
init <- c(init, si.flow = 0, ir.flow = 0,
si.flow.g2 = 0, ir.flow.g2 = 0)
} else {
model <- mod_SIR_2g_op
init <- c(init, si.flow = 0, ir.flow = 0, a.flow = 0,
ds.flow = 0, di.flow = 0, dr.flow = 0,
si.flow.g2 = 0, ir.flow.g2 = 0, a.flow.g2 = 0,
ds.flow.g2 = 0, di.flow.g2 = 0, dr.flow.g2 = 0)
}
}
}
if (control$type == "SIS") {
if (param$groups == 1) {
if (param$vital == FALSE) {
model <- mod_SIS_1g_cl
init <- c(init, si.flow = 0, is.flow = 0)
} else {
model <- mod_SIS_1g_op
init <- c(init, si.flow = 0, is.flow = 0,
a.flow = 0, ds.flow = 0, di.flow = 0)
}
} else {
if (param$vital == FALSE) {
model <- mod_SIS_2g_cl
init <- c(init, si.flow = 0, is.flow = 0,
si.flow.g2 = 0, is.flow.g2 = 0)
} else {
model <- mod_SIS_2g_op
init <- c(init, si.flow = 0, is.flow = 0,
a.flow = 0, ds.flow = 0, di.flow = 0,
si.flow.g2 = 0, is.flow.g2 = 0,
a.flow.g2 = 0, ds.flow.g2 = 0, di.flow.g2 = 0)
}
}
}
} else {
# Sub in new model
model <- control$new.mod
}
# Print model option ------------------------------------------------------
if (control$print.mod == TRUE) {
return(print(model))
}
# Initial conditions ------------------------------------------------------
t0 <- setNames(as.numeric(init), names(init))
# Sensitivity parameters --------------------------------------------------
if (control$sens.param == FALSE) {
control$nruns <- 1
} else {
control$nruns <- max(sapply(param, length))
}
if (control$nruns > 1) {
longv <- which(sapply(param, length) == max(sapply(param, length)))
longvn <- names(longv)
lim.p <- param[!(names(param) %in% longvn)]
}
# Model runs --------------------------------------------------------------
verbose.dcm(control, type = "startup")
for (s in 1:control$nruns) {
## Sensitivity parameter input
if (control$nruns > 1) {
all.p <- as.list(lim.p)
for (j in seq_along(longvn)) {
sens.p <- param[[longvn[j]]][s]
all.p[[longvn[j]]] <- sens.p
}
} else {
all.p <- param
}
## Timesteps
if (length(control$nsteps) == 1) {
times <- seq(1, control$nsteps, control$dt)
} else {
times <- control$nsteps
}
## Differential equation solvers
if (control$dede == FALSE) {
df <- data.frame(ode(y = t0,
times = times,
func = model,
parms = all.p,
method = control$odemethod))
} else {
df <- data.frame(dede(y = t0,
times = times,
func = model,
parms = all.p))
}
## Recalculate Flows
isFlow <- grep(".flow", x = names(df))
if (length(isFlow) > 0) {
for (j in isFlow) {
df[, j] <- c(diff(df[, j]), NA)
}
}
# Output ------------------------------------------------------------------
## Save to out object
if (s == 1) {
out <- saveout.dcm(df, s, param, control)
} else {
out <- saveout.dcm(df, s, param, control, out)
}
## Progress
verbose.dcm(control, type = "progress", s)
}
class(out) <- "dcm"
invisible(out)
}
statnet/EpiModel documentation built on March 30, 2024, 11:26 a.m.
R Package Documentation
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Defines functions dcm
Documented in dcm
#' @title Deterministic Compartmental Models
#'
#' @description Solves deterministic compartmental epidemic models for
#' infectious disease.
#'
#' @param param Model parameters, as an object of class \code{\link{param.dcm}}.
#' @param init Initial conditions, as an object of class \code{\link{init.dcm}}.
#' @param control Control settings, as an object of class
#' \code{\link{control.dcm}}.
#'
#' @details
#' The \code{dcm} function uses the ordinary differential equation solver in
#' the \code{deSolve} package to model disease as a deterministic compartmental
#' system. The parameterization for these models follows the standard approach
#' in \code{EpiModel}, with epidemic parameters, initial conditions, and control
#' settings. A description of solving DCMs with the \code{dcm} function may be
#' found in the \href{http://www.epimodel.org/tut.html}{Basic DCMs} tutorial.
#'
#' The \code{dcm} function performs modeling of both base model types and
#' original models with new structures. Base model types include one-group
#' and two-group models with disease types for Susceptible-Infected (SI),
#' Susceptible-Infected-Recovered (SIR), and Susceptible-Infected-Susceptible
#' (SIS). New model types may be written and input into \code{dcm} following the
#' steps outlined in the \href{http://www.epimodel.org/tut.html}{New DCMs}
#' tutorial. Both base and original models require the \code{param},
#' \code{init}, and \code{control} inputs.
#'
#' @return
#' A list of class \code{dcm} with the following elements:
#' \itemize{
#' \item \strong{param:} the epidemic parameters passed into the model through
#' \code{param}, with additional parameters added as necessary.
#' \item \strong{control:} the control settings passed into the model through
#' \code{control}, with additional controls added as necessary.
#' \item \strong{epi:} a list of data frames, one for each epidemiological
#' output from the model. Outputs for base models always include the
#' size of each compartment, as well as flows in, out of, and between
#' compartments.
#' }
#'
#' @references
#' Soetaert K, Petzoldt T, Setzer W. Solving Differential Equations in
#' R: Package deSolve. Journal of Statistical Software. 2010; 33(9): 1-25.
#' \doi{10.18637/jss.v033.i09}.
#'
#' @keywords model
#'
#' @seealso Extract the model results with \code{\link{as.data.frame.dcm}}.
#' Summarize the time-specific model results with \code{\link{summary.dcm}}.
#' Plot the model results with \code{\link{plot.dcm}}. Plot a compartment flow
#' diagram with \code{\link{comp_plot}}.
#'
#' @export
#'
#' @examples
#' ## Example 1: SI Model (One-Group)
#' # Set parameters
#' param <- param.dcm(inf.prob = 0.2, act.rate = 0.25)
#' init <- init.dcm(s.num = 500, i.num = 1)
#' control <- control.dcm(type = "SI", nsteps = 500)
#' mod1 <- dcm(param, init, control)
#' mod1
#' plot(mod1)
#'
#' ## Example 2: SIR Model with Vital Dynamics (One-Group)
#' param <- param.dcm(inf.prob = 0.2, act.rate = 5,
#' rec.rate = 1/3, a.rate = 1/90, ds.rate = 1/100,
#' di.rate = 1/35, dr.rate = 1/100)
#' init <- init.dcm(s.num = 500, i.num = 1, r.num = 0)
#' control <- control.dcm(type = "SIR", nsteps = 500)
#' mod2 <- dcm(param, init, control)
#' mod2
#' plot(mod2)
#'
#' ## Example 3: SIS Model with act.rate Sensitivity Parameter
#' param <- param.dcm(inf.prob = 0.2, act.rate = seq(0.1, 0.5, 0.1),
#' rec.rate = 1/50)
#' init <- init.dcm(s.num = 500, i.num = 1)
#' control <- control.dcm(type = "SIS", nsteps = 500)
#' mod3 <- dcm(param, init, control)
#' mod3
#' plot(mod3)
#'
#' ## Example 4: SI Model with Vital Dynamics (Two-Group)
#' param <- param.dcm(inf.prob = 0.4, inf.prob.g2 = 0.1,
#' act.rate = 0.25, balance = "g1",
#' a.rate = 1/100, a.rate.g2 = NA,
#' ds.rate = 1/100, ds.rate.g2 = 1/100,
#' di.rate = 1/50, di.rate.g2 = 1/50)
#' init <- init.dcm(s.num = 500, i.num = 1,
#' s.num.g2 = 500, i.num.g2 = 0)
#' control <- control.dcm(type = "SI", nsteps = 500)
#' mod4 <- dcm(param, init, control)
#' mod4
#' plot(mod4)
#'
dcm <- function(param, init, control) {
check.control.class("dcm", "EpiModel dcm")
crosscheck.dcm(param, init, control)
# Model selection ---------------------------------------------------------
if (is.null(control$new.mod)) {
if (control$type == "SI") {
if (param$groups == 1) {
if (param$vital == FALSE) {
model <- mod_SI_1g_cl
init <- c(init, si.flow = 0)
} else {
model <- mod_SI_1g_op
init <- c(init, si.flow = 0, a.flow = 0, ds.flow = 0, di.flow = 0)
}
} else {
if (param$vital == FALSE) {
model <- mod_SI_2g_cl
init <- c(init, si.flow = 0, si.flow.g2 = 0)
} else {
model <- mod_SI_2g_op
init <- c(init,
si.flow = 0, a.flow = 0, ds.flow = 0, di.flow = 0,
si.flow.g2 = 0, a.flow.g2 = 0, ds.flow.g2 = 0,
di.flow.g2 = 0)
}
}
}
if (control$type == "SIR") {
if (param$groups == 1) {
if (param$vital == FALSE) {
model <- mod_SIR_1g_cl
init <- c(init, si.flow = 0, ir.flow = 0)
} else {
model <- mod_SIR_1g_op
init <- c(init, si.flow = 0, ir.flow = 0, a.flow = 0,
ds.flow = 0, di.flow = 0, dr.flow = 0)
}
} else {
if (param$vital == FALSE) {
model <- mod_SIR_2g_cl
init <- c(init, si.flow = 0, ir.flow = 0,
si.flow.g2 = 0, ir.flow.g2 = 0)
} else {
model <- mod_SIR_2g_op
init <- c(init, si.flow = 0, ir.flow = 0, a.flow = 0,
ds.flow = 0, di.flow = 0, dr.flow = 0,
si.flow.g2 = 0, ir.flow.g2 = 0, a.flow.g2 = 0,
ds.flow.g2 = 0, di.flow.g2 = 0, dr.flow.g2 = 0)
}
}
}
if (control$type == "SIS") {
if (param$groups == 1) {
if (param$vital == FALSE) {
model <- mod_SIS_1g_cl
init <- c(init, si.flow = 0, is.flow = 0)
} else {
model <- mod_SIS_1g_op
init <- c(init, si.flow = 0, is.flow = 0,
a.flow = 0, ds.flow = 0, di.flow = 0)
}
} else {
if (param$vital == FALSE) {
model <- mod_SIS_2g_cl
init <- c(init, si.flow = 0, is.flow = 0,
si.flow.g2 = 0, is.flow.g2 = 0)
} else {
model <- mod_SIS_2g_op
init <- c(init, si.flow = 0, is.flow = 0,
a.flow = 0, ds.flow = 0, di.flow = 0,
si.flow.g2 = 0, is.flow.g2 = 0,
a.flow.g2 = 0, ds.flow.g2 = 0, di.flow.g2 = 0)
}
}
}
} else {
# Sub in new model
model <- control$new.mod
}
# Print model option ------------------------------------------------------
if (control$print.mod == TRUE) {
return(print(model))
}
# Initial conditions ------------------------------------------------------
t0 <- setNames(as.numeric(init), names(init))
# Sensitivity parameters --------------------------------------------------
if (control$sens.param == FALSE) {
control$nruns <- 1
} else {
control$nruns <- max(sapply(param, length))
}
if (control$nruns > 1) {
longv <- which(sapply(param, length) == max(sapply(param, length)))
longvn <- names(longv)
lim.p <- param[!(names(param) %in% longvn)]
}
# Model runs --------------------------------------------------------------
verbose.dcm(control, type = "startup")
for (s in 1:control$nruns) {
## Sensitivity parameter input
if (control$nruns > 1) {
all.p <- as.list(lim.p)
for (j in seq_along(longvn)) {
sens.p <- param[[longvn[j]]][s]
all.p[[longvn[j]]] <- sens.p
}
} else {
all.p <- param
}
## Timesteps
if (length(control$nsteps) == 1) {
times <- seq(1, control$nsteps, control$dt)
} else {
times <- control$nsteps
}
## Differential equation solvers
if (control$dede == FALSE) {
df <- data.frame(ode(y = t0,
times = times,
func = model,
parms = all.p,
method = control$odemethod))
} else {
df <- data.frame(dede(y = t0,
times = times,
func = model,
parms = all.p))
}
## Recalculate Flows
isFlow <- grep(".flow", x = names(df))
if (length(isFlow) > 0) {
for (j in isFlow) {
df[, j] <- c(diff(df[, j]), NA)
}
}
# Output ------------------------------------------------------------------
## Save to out object
if (s == 1) {
out <- saveout.dcm(df, s, param, control)
} else {
out <- saveout.dcm(df, s, param, control, out)
}
## Progress
verbose.dcm(control, type = "progress", s)
}
class(out) <- "dcm"
invisible(out)
}
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