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Delaigue Olivier authoredc672655f
\encoding{UTF-8}\name{RunModel_CemaNeigeGR5H}\alias{RunModel_CemaNeigeGR5H}\title{Run with the CemaNeigeGR5H hydrological model}\description{Function which performs a single run for the CemaNeige-GR5H hourly lumped model over the test period.}\usage{RunModel_CemaNeigeGR5H(InputsModel, RunOptions, Param)}\arguments{\item{InputsModel}{[object of class \emph{InputsModel}] see \code{\link{CreateInputsModel}} for details}\item{RunOptions}{[object of class \emph{RunOptions}] see \code{\link{CreateRunOptions}} for details}\item{Param}{[numeric] vector of 7 (or 9 parameters if \code{IsHyst = TRUE}, see \code{\link{CreateRunOptions}} for details) \tabular{ll}{ GR5H X1 \tab production store capacity [mm] \cr GR5H X2 \tab intercatchment exchange coefficient [mm/h] \cr GR5H X3 \tab routing store capacity [mm] \cr GR5H X4 \tab unit hydrograph time constant [h] \cr GR5H X5 \tab intercatchment exchange threshold [-] \cr CemaNeige X1 \tab weighting coefficient for snow pack thermal state [-] \cr CemaNeige X2 \tab degree-hour melt coefficient [mm/°C/h] \cr CemaNeige X3 \tab (optional) accumulation threshold [mm] (needed if \code{IsHyst = TRUE}) \cr CemaNeige X4 \tab (optional) percentage (between 0 and 1) of annual snowfall defining the melt threshold [-] (needed if \code{IsHyst = TRUE}) \cr }}}\value{[list] containing the function outputs organised as follows: \tabular{ll}{ \emph{$DatesR } \tab [POSIXlt] series of dates \cr \emph{$PotEvap } \tab [numeric] series of input potential evapotranspiration (E) [mm/h] \cr \emph{$Precip } \tab [numeric] series of input total precipitation (P) [mm/h] \cr \emph{$Interc } \tab [numeric] series of interception store level (I) [mm] \cr \emph{$Prod } \tab [numeric] series of production store level (S) [mm] \cr \emph{$Pn } \tab [numeric] series of net rainfall (Pn) [mm/h] \cr \emph{$Ps } \tab [numeric] series of the part of Pn filling the production store (Ps) [mm/h] \cr \emph{$AE } \tab [numeric] series of actual evapotranspiration (Ei+Es) [mm/h] \cr \emph{$EI } \tab [numeric] series of evapotranspiration from rainfall neutralisation or interception store (Ei) [mm/h] \cr \emph{$ES } \tab [numeric] series of evapotranspiration from production store (Es) [mm/h] \cr \emph{$Perc } \tab [numeric] series of percolation (Perc) [mm/h] \cr \emph{$PR } \tab [numeric] series of Pr=Pn-Ps+Perc (Pr) [mm/h] \cr \emph{$Q9 } \tab [numeric] series of UH outflow going into branch 9 (Q9) [mm/h] \cr \emph{$Q1 } \tab [numeric] series of UH outflow going into branch 1 (Q1) [mm/h] \cr \emph{$Rout } \tab [numeric] series of routing store level (R1) [mm] \cr \emph{$Exch } \tab [numeric] series of potential semi-exchange between catchments [mm/h] \cr \emph{$AExch1 } \tab [numeric] series of actual exchange between catchments for branch 1 [mm/h] \cr \emph{$AExch2 } \tab [numeric] series of actual exchange between catchments for branch 2 [mm/h] \cr \emph{$AExch } \tab [numeric] series of actual exchange between catchments (AExch1+AExch2) [mm/h] \cr \emph{$QR } \tab [numeric] series of routing store outflow (Qr) [mm/h] \cr \emph{$QD } \tab [numeric] series of direct flow from UH after exchange (Qd) [mm/h] \cr \emph{$Qsim } \tab [numeric] series of simulated discharge (Q) [mm/h] \cr \emph{$CemaNeigeLayers} \tab [list] CemaNeige outputs (1 element per layer) \cr \emph{$CemaNeigeLayers[[iLayer]]$Pliq } \tab [numeric] series of liquid precip. [mm/h] \cr \emph{$CemaNeigeLayers[[iLayer]]$Psol } \tab [numeric] series of solid precip. [mm/h] \cr \emph{$CemaNeigeLayers[[iLayer]]$SnowPack } \tab [numeric] series of snow pack (snow water equivalent) [mm] \cr \emph{$CemaNeigeLayers[[iLayer]]$ThermalState } \tab [numeric] series of snow pack thermal state [°C] \cr7172737475767778798081828384858687888990919293949596979899100101102103104105106107108109110111112113114115116117118119120121122123124125126127128129130131132133134135136137138139140
\emph{$CemaNeigeLayers[[iLayer]]$Gratio } \tab [numeric] series of Gratio [0-1] \cr
\emph{$CemaNeigeLayers[[iLayer]]$PotMelt } \tab [numeric] series of potential snow melt [mm/h] \cr
\emph{$CemaNeigeLayers[[iLayer]]$Melt } \tab [numeric] series of actual snow melt [mm/h] \cr
\emph{$CemaNeigeLayers[[iLayer]]$PliqAndMelt } \tab [numeric] series of liquid precip. + actual snow melt [mm/h] \cr
\emph{$CemaNeigeLayers[[iLayer]]$Temp } \tab [numeric] series of air temperature [°C] \cr
\emph{$CemaNeigeLayers[[iLayer]]$Gthreshold } \tab [numeric] series of melt threshold [mm] \cr
\emph{$CemaNeigeLayers[[iLayer]]$Glocalmax } \tab [numeric] series of local melt threshold for hysteresis [mm] \cr
\emph{RunOptions$WarmUpQsim} \tab [numeric] series of simulated discharge (Q) on the warm-up period [mm/h] \cr
\emph{RunOptions$Param } \tab [numeric] parameter set parameter set used by the model \cr
\emph{$StateEnd} \tab [numeric] states at the end of the run: store & unit hydrographs levels [mm], CemaNeige states [mm & °C]. See \code{\link{CreateIniStates}} for more details \cr
}
Refer to the provided references or to the package source code for further details on these model outputs.
}
\details{
The choice of the CemaNeige version is explained in \code{\link{CreateRunOptions}}. \cr
For further details on the model, see the references section. \cr
For further details on the argument structures and initialisation options, see \code{\link{CreateRunOptions}}.
\cr
\cr
See \code{\link{RunModel_GR5H}} to look at the diagram of the hydrological model or \code{\link{RunModel_GR5J}} when no interception store is used.
}
\examples{
\dontrun{
library(airGR)
## loading catchment data
data(U2345030)
## preparation of the InputsModel object
InputsModel <- CreateInputsModel(FUN_MOD = RunModel_CemaNeigeGR5H, DatesR = BasinObs$DatesR,
Precip = BasinObs$P, PotEvap = BasinObs$E, TempMean = BasinObs$T,
ZInputs = BasinInfo$ZInputs,
HypsoData = BasinInfo$HypsoData, NLayers = 5)
## run period selection
Ind_Run <- seq(which(format(BasinObs$DatesR, format = "\%Y-\%m-\%d \%H")=="2004-03-01 00"),
which(format(BasinObs$DatesR, format = "\%Y-\%m-\%d \%H")=="2008-12-31 23"))
## --- original version of CemaNeige
## Imax computation
Imax <- Imax(InputsModel = InputsModel, IndPeriod_Run = Ind_Run,
TestedValues = seq(from = 0, to = 3, by = 0.2))
## preparation of the RunOptions object
RunOptions <- CreateRunOptions(FUN_MOD = RunModel_CemaNeigeGR5H, InputsModel = InputsModel,
Imax = Imax, IndPeriod_Run = Ind_Run)
## simulation
Param <- c(X1 = 218.537, X2 = -0.009, X3 = 174.862, X4 = 6.674, X5 = 0.000,
CNX1 = 0.002, CNX2 = 3.787)
OutputsModel <- RunModel_CemaNeigeGR5H(InputsModel = InputsModel,
RunOptions = RunOptions, Param = Param)
## results preview
plot(OutputsModel, Qobs = BasinObs$Qmm[Ind_Run])
## efficiency criterion: Nash-Sutcliffe Efficiency
InputsCrit <- CreateInputsCrit(FUN_CRIT = ErrorCrit_NSE, InputsModel = InputsModel,
RunOptions = RunOptions, Obs = BasinObs$Qmm[Ind_Run])
OutputsCrit <- ErrorCrit_NSE(InputsCrit = InputsCrit, OutputsModel = OutputsModel)
}
}
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\author{
Laurent Coron, Guillaume Thirel, Olivier Delaigue, Audrey Valéry, Vazken Andréassian
}
\references{
Ficchi, A. (2017).
An adaptive hydrological model for multiple time-steps:
Diagnostics and improvements based on fluxes consistency.
PhD thesis, UPMC - Irstea Antony, Paris, France.
\cr\cr
Ficchi, A., Perrin, C. and Andréassian, V. (2019).
Hydrological modelling at multiple sub-daily time steps: model improvement via flux-matching.
Journal of Hydrology, 575, 1308-1327, \doi{10.1016/j.jhydrol.2019.05.084}.
\cr\cr
Perrin, C., Michel, C. and Andréassian, V. (2003).
Improvement of a parsimonious model for streamflow simulation.
Journal of Hydrology, 279(1-4), 275-289, \doi{10.1016/S0022-1694(03)00225-7}.
\cr\cr
Riboust, P., Thirel, G., Le Moine, N. and Ribstein, P. (2019).
Revisiting a simple degree-day model for integrating satellite data: Implementation of SWE-SCA hystereses.
Journal of Hydrology and Hydromechanics, 67(1), 70–81, \doi{10.2478/johh-2018-0004}.
\cr\cr
Valéry, A., Andréassian, V. and Perrin, C. (2014).
"As simple as possible but not simpler": What is useful in a temperature-based snow-accounting routine?
Part 1 - Comparison of six snow accounting routines on 380 catchments.
Journal of Hydrology, 517(0), 1166-1175, \doi{10.1016/j.jhydrol.2014.04.059}.
\cr\cr
Valéry, A., Andréassian, V. and Perrin, C. (2014).
"As simple as possible but not simpler": What is useful in a temperature-based snow-accounting routine?
Part 2 - Sensitivity analysis of the Cemaneige snow accounting routine on 380 catchments.
Journal of Hydrology, 517(0), 1176-1187, \doi{10.1016/j.jhydrol.2014.04.058}.
}
\seealso{
\code{\link{RunModel_CemaNeige}}, \code{\link{RunModel_CemaNeigeGR4H}}, \code{\link{RunModel_GR5H}}, \code{\link{Imax}},
\code{\link{CreateInputsModel}}, \code{\link{CreateRunOptions}}, \code{\link{CreateIniStates}}.
}