\emph{IndPeriod_WarmUp } \tab [numeric] index of period to be used for the model warm-up [-] \cr
\emph{IndPeriod_WarmUp } \tab [numeric] index of period to be used for the model warm-up [-] \cr
\emph{IndPeriod_Run } \tab [numeric] index of period to be used for the model run [-] \cr
\emph{IndPeriod_Run } \tab [numeric] index of period to be used for the model run [-] \cr
\emph{IniStates } \tab [numeric] vector of initial model states [mm and °C] \cr
\emph{IniStates } \tab [numeric] vector of initial model states [mm and °C] \cr
\emph{IniResLevels } \tab [numeric] vector of initial filling rates for production and routing stores [-] and level fothe the exponential store for GR6J [mm]\cr
\emph{IniResLevels } \tab [numeric] vector of initial filling rates for production and routing stores [-] and level for the exponential store for GR6J [mm]\cr
\emph{Outputs_Cal } \tab [character] character vector giving only the outputs needed for the calibration \cr
\emph{Outputs_Cal } \tab [character] character vector giving only the outputs needed for the calibration \cr
\emph{Outputs_Sim } \tab [character] character vector giving the requested outputs \cr
\emph{Outputs_Sim } \tab [character] character vector giving the requested outputs \cr
\emph{MeanAnSolidPrecip} \tab [numeric] vector giving the annual mean of average solid precipitation for each layer [mm/y] \cr
\emph{MeanAnSolidPrecip} \tab [numeric] vector giving the annual mean of average solid precipitation for each layer [mm/y] \cr
...
@@ -97,7 +97,7 @@ However, it is also possible to perform a long-term initialisation if other indi
...
@@ -97,7 +97,7 @@ However, it is also possible to perform a long-term initialisation if other indi
\item remark 2: if \code{IniStates} is used, two possibilities are offered:\cr
\item remark 2: if \code{IniStates} is used, two possibilities are offered:\cr
- \code{IniStates} can be set to the \emph{$StateEnd} output of a previous \code{RunModel} call, as \emph{$StateEnd} already respects the correct format; \cr
- \code{IniStates} can be set to the \emph{$StateEnd} output of a previous \code{RunModel} call, as \emph{$StateEnd} already respects the correct format; \cr
- \code{IniStates} can be created with the \code{\link{CreateIniStates}} function.
- \code{IniStates} can be created with the \code{\link{CreateIniStates}} function.
\item remark 3: in addition to \code{IniStates}, \code{IniResLevels} allows to set the filling rate of the production and routing stores for the GR models. For instance for GR4J and GR5J: \code{IniResLevels = c(0.3, 0.5)} should be used to obtain initial fillings of 30 \% and 50 \% for the production and routing stores, respectively. For GR6J, \code{IniResLevels = c(0.3, 0.5, 0)} shold be use to obtain initial fillings of 30 \% and 50 \% for the production, routing stores and 0 mm for the exponential store, respectively. \code{IniResLevels} is optional and can only be used if \code{IniStates} is also defined (the state values corresponding to these two other stores in \code{IniStates} are not used in such case).
\item remark 3: in addition to \code{IniStates}, \code{IniResLevels} allows to set the filling rate of the production and routing stores for the GR models. For instance for GR4J and GR5J: \code{IniResLevels = c(0.3, 0.5)} should be used to obtain initial fillings of 30 \% and 50 \% for the production and routing stores, respectively. For GR6J, \code{IniResLevels = c(0.3, 0.5, 0)} should be use to obtain initial fillings of 30 \% and 50 \% for the production, routing stores and 0 mm for the exponential store, respectively. \code{IniResLevels} is optional and can only be used if \code{IniStates} is also defined (the state values corresponding to these two other stores in \code{IniStates} are not used in such case).