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Commit 68007cd4 authored by Delaigue Olivier's avatar Delaigue Olivier
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v1.2.12.15 DOC: inputs and outputs lists re-indented in many docs

parent 05ad4571
dev 115-add-pcict-date-format-managment 118-plot-outputsmodel-remove-case-sensitivity-to-the-which-argument 136-decreased-performance-of-calibration-execution-time 60-migrate-transfoparam-functions-and-createcaliboptions-to-s3-methods 96-parallelize-the-grid-screening-step-during-calibration airGRplus cleanAirGRplus master CRAN_v1.7.0 CRAN_v1.6.12 CRAN_v1.6.11 CRAN_v1.6.10.4 CRAN_v1.6.9.27 CRAN_v1.6.9.24 CRAN_v1.6.9.23 CRAN_v1.6.9.21 CRAN_v1.4.3.65 CRAN_v1.4.3.60 CRAN_v1.4.3.52 CRAN_v1.3.2.42 CRAN_v1.3.2.41 CRAN_v1.3.2.40 CRAN_v1.3.2.39 CRAN_v1.3.2.23 CRAN_v1.3.2.17 CRAN_v1.2.13.16 CRAN_v1.2.13.13
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DESCRIPTION
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Package: airGR Package: airGR
Type: Package Type: Package
Title: Suite of GR Hydrological Models for Precipitation-Runoff Modelling Title: Suite of GR Hydrological Models for Precipitation-Runoff Modelling
Version: 1.2.12.14 Version: 1.2.12.15
Date: 2019-04-01 Date: 2019-04-01
Authors@R: c( Authors@R: c(
person("Laurent", "Coron", role = c("aut", "trl"), comment = c(ORCID = "0000-0002-1503-6204")), person("Laurent", "Coron", role = c("aut", "trl"), comment = c(ORCID = "0000-0002-1503-6204")),
......
NEWS.rmd
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...@@ -13,7 +13,7 @@ output: ...@@ -13,7 +13,7 @@ output:
### 1.2.12.14 Release Notes (2019-04-01) ### 1.2.12.15 Release Notes (2019-04-01)
......
man/CreateIniStates.Rd
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...@@ -48,11 +48,11 @@ CreateIniStates(FUN_MOD, InputsModel, ...@@ -48,11 +48,11 @@ CreateIniStates(FUN_MOD, InputsModel,
\value{ \value{
[list] object of class \code{IniStates} containing the initial model internal states; it always includes the following: [list] object of class \code{IniStates} containing the initial model internal states; it always includes the following:
\tabular{ll}{ \tabular{ll}{
\emph{$Store } \tab [numeric] list of store levels (\emph{$Prod}, \emph{$Rout} and \emph{$Exp}) \cr \emph{$Store } \tab [numeric] list of store levels (\emph{$Prod}, \emph{$Rout} and \emph{$Exp}) \cr
\emph{$UH } \tab [numeric] list of unit hydrographs levels (\emph{$UH1} and \emph{$UH2}) \cr \emph{$UH } \tab [numeric] list of unit hydrographs levels (\emph{$UH1} and \emph{$UH2}) \cr
\emph{$CemaNeigeLayers} \tab [numeric] list of CemaNeige variables (\emph{$G} and \emph{$eTG}) \emph{$CemaNeigeLayers} \tab [numeric] list of CemaNeige variables (\emph{$G} and \emph{$eTG})
} }
} }
...@@ -140,4 +140,3 @@ Olivier Delaigue ...@@ -140,4 +140,3 @@ Olivier Delaigue
\seealso{ \seealso{
\code{\link{CreateRunOptions}} \code{\link{CreateRunOptions}}
} }
man/CreateInputsModel.Rd
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...@@ -48,8 +48,8 @@ CreateInputsModel(FUN_MOD, DatesR, Precip, PrecipScale = TRUE, PotEvap = NULL, ...@@ -48,8 +48,8 @@ CreateInputsModel(FUN_MOD, DatesR, Precip, PrecipScale = TRUE, PotEvap = NULL,
\emph{$DatesR } \tab [POSIXlt] vector of dates \cr \emph{$DatesR } \tab [POSIXlt] vector of dates \cr
\emph{$Precip } \tab [numeric] time series of total precipitation (catchment average) [mm/time step] \cr \emph{$Precip } \tab [numeric] time series of total precipitation (catchment average) [mm/time step] \cr
\emph{$PotEvap } \tab [numeric] time series of potential evapotranspiration (catchment average) [mm/time step], \cr\tab defined if FUN_MOD includes GR4H, GR4J, GR5J, GR6J, GR2M or GR1A \cr \cr \emph{$PotEvap } \tab [numeric] time series of potential evapotranspiration (catchment average) [mm/time step], \cr\tab defined if FUN_MOD includes GR4H, GR4J, GR5J, GR6J, GR2M or GR1A \cr \cr
\emph{$LayerPrecip } \tab [list] list of time series of precipitation (layer average) [mm/time step], \cr\tab defined if \code{FUN_MOD} includes CemaNeige \cr \cr \emph{$LayerPrecip } \tab [list] list of time series of precipitation (layer average) [mm/time step], \cr\tab defined if \code{FUN_MOD} includes CemaNeige \cr \cr
\emph{$LayerTempMean } \tab [list] list of time series of mean air temperature (layer average) [°C], \cr\tab defined if \code{FUN_MOD} includes CemaNeige \cr \cr \emph{$LayerTempMean } \tab [list] list of time series of mean air temperature (layer average) [°C], \cr\tab defined if \code{FUN_MOD} includes CemaNeige \cr \cr
\emph{$LayerFracSolidPrecip} \tab [list] list of time series of solid precipitation fraction (layer average) [-], \cr\tab defined if \code{FUN_MOD} includes CemaNeige \cr \cr \emph{$LayerFracSolidPrecip} \tab [list] list of time series of solid precipitation fraction (layer average) [-], \cr\tab defined if \code{FUN_MOD} includes CemaNeige \cr \cr
} }
} }
......
man/DataAltiExtrapolation_Valery.Rd
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...@@ -39,12 +39,12 @@ DataAltiExtrapolation_Valery(DatesR, Precip, PrecipScale = TRUE, ...@@ -39,12 +39,12 @@ DataAltiExtrapolation_Valery(DatesR, Precip, PrecipScale = TRUE,
\value{ \value{
list containing the extrapolated series of precip. and air temp. on each elevation layer list containing the extrapolated series of precip. and air temp. on each elevation layer
\tabular{ll}{ \tabular{ll}{
\emph{$LayerPrecip } \tab [list] list of time series of daily precipitation (layer average) [mm/d] \cr \emph{$LayerPrecip } \tab [list] list of time series of daily precipitation (layer average) [mm/d] \cr
\emph{$LayerTempMean } \tab [list] list of time series of daily mean air temperature (layer average) [°C] \cr \emph{$LayerTempMean } \tab [list] list of time series of daily mean air temperature (layer average) [°C] \cr
\emph{$LayerTempMin } \tab [list] list of time series of daily min air temperature (layer average) [°C] \cr \emph{$LayerTempMin } \tab [list] list of time series of daily min air temperature (layer average) [°C] \cr
\emph{$LayerTempMax } \tab [list] list of time series of daily max air temperature (layer average) [°C] \cr \emph{$LayerTempMax } \tab [list] list of time series of daily max air temperature (layer average) [°C] \cr
\emph{$LayerFracSolidPrecip} \tab [list] list of time series of daily solid precip. fract. (layer average) [-] \cr \emph{$LayerFracSolidPrecip} \tab [list] list of time series of daily solid precip. fract. (layer average) [-] \cr
\emph{$ZLayers } \tab [numeric] vector of median elevation for each layer \cr \emph{$ZLayers } \tab [numeric] vector of median elevation for each layer \cr
} }
} }
......
man/Param_Sets_GR4J.Rd
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...@@ -11,9 +11,9 @@ ...@@ -11,9 +11,9 @@
\format{Data frame of parameters containing four numeric vectors \format{Data frame of parameters containing four numeric vectors
\itemize{ \itemize{
\item {GR4J X1} {production store capacity [mm]} \item {GR4J X1} {production store capacity [mm]}
\item {GR4J X2} {intercatchment exchange coefficient [mm/d]} \item {GR4J X2} {intercatchment exchange coefficient [mm/d]}
\item {GR4J X3} {routing store capacity [mm]} \item {GR4J X3} {routing store capacity [mm]}
\item {GR4J X4u} {unajusted unit hydrograph time constant [d]} \item {GR4J X4u} {unajusted unit hydrograph time constant [d]}
}} }}
......
man/RunModel_CemaNeigeGR4J.Rd
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...@@ -34,41 +34,41 @@ CemaNeige X4 \tab (optional) percentage (between 0 and 1) of annual snowfall def ...@@ -34,41 +34,41 @@ CemaNeige X4 \tab (optional) percentage (between 0 and 1) of annual snowfall def
\value{ \value{
[list] list containing the function outputs organised as follows: [list] list containing the function outputs organised as follows:
\tabular{ll}{ \tabular{ll}{
\emph{$DatesR } \tab [POSIXlt] series of dates \cr \emph{$DatesR } \tab [POSIXlt] series of dates \cr
\emph{$PotEvap } \tab [numeric] series of input potential evapotranspiration [mm/d] \cr \emph{$PotEvap } \tab [numeric] series of input potential evapotranspiration [mm/d] \cr
\emph{$Precip } \tab [numeric] series of input total precipitation [mm/d] \cr \emph{$Precip } \tab [numeric] series of input total precipitation [mm/d] \cr
\emph{$Prod } \tab [numeric] series of production store level [mm] \cr \emph{$Prod } \tab [numeric] series of production store level [mm] \cr
\emph{$Pn } \tab [numeric] series of net rainfall [mm/d] \cr \emph{$Pn } \tab [numeric] series of net rainfall [mm/d] \cr
\emph{$Ps } \tab [numeric] series of the part of Pn filling the production store [mm/d] \cr \emph{$Ps } \tab [numeric] series of the part of Pn filling the production store [mm/d] \cr
\emph{$AE } \tab [numeric] series of actual evapotranspiration [mm/d] \cr \emph{$AE } \tab [numeric] series of actual evapotranspiration [mm/d] \cr
\emph{$Perc } \tab [numeric] series of percolation (PERC) [mm/d] \cr \emph{$Perc } \tab [numeric] series of percolation (PERC) [mm/d] \cr
\emph{$PR } \tab [numeric] series of PR=Pn-Ps+Perc [mm/d] \cr \emph{$PR } \tab [numeric] series of PR=Pn-Ps+Perc [mm/d] \cr
\emph{$Q9 } \tab [numeric] series of UH1 outflow (Q9) [mm/d] \cr \emph{$Q9 } \tab [numeric] series of UH1 outflow (Q9) [mm/d] \cr
\emph{$Q1 } \tab [numeric] series of UH2 outflow (Q1) [mm/d] \cr \emph{$Q1 } \tab [numeric] series of UH2 outflow (Q1) [mm/d] \cr
\emph{$Rout } \tab [numeric] series of routing store level [mm] \cr \emph{$Rout } \tab [numeric] series of routing store level [mm] \cr
\emph{$Exch } \tab [numeric] series of potential semi-exchange between catchments [mm/d] \cr \emph{$Exch } \tab [numeric] series of potential semi-exchange between catchments [mm/d] \cr
\emph{$AExch1 } \tab [numeric] series of actual exchange between catchments for branch 1 [mm/d] \cr \emph{$AExch1 } \tab [numeric] series of actual exchange between catchments for branch 1 [mm/d] \cr
\emph{$AExch2 } \tab [numeric] series of actual exchange between catchments for branch 2 [mm/d] \cr \emph{$AExch2 } \tab [numeric] series of actual exchange between catchments for branch 2 [mm/d] \cr
\emph{$AExch } \tab [numeric] series of actual exchange between catchments (1+2) [mm/d] \cr \emph{$AExch } \tab [numeric] series of actual exchange between catchments (1+2) [mm/d] \cr
\emph{$QR } \tab [numeric] series of routing store outflow (QR) [mm/d] \cr \emph{$QR } \tab [numeric] series of routing store outflow (QR) [mm/d] \cr
\emph{$QD } \tab [numeric] series of direct flow from UH2 after exchange (QD) [mm/d] \cr \emph{$QD } \tab [numeric] series of direct flow from UH2 after exchange (QD) [mm/d] \cr
\emph{$Qsim } \tab [numeric] series of simulated discharge [mm/d] \cr \emph{$Qsim } \tab [numeric] series of simulated discharge [mm/d] \cr
\emph{$CemaNeigeLayers} \tab [list] list of CemaNeige outputs (1 list per layer) \cr \emph{$CemaNeigeLayers} \tab [list] list of CemaNeige outputs (1 list per layer) \cr
\emph{$CemaNeigeLayers[[iLayer]]$Pliq } \tab [numeric] series of liquid precip. [mm/d] \cr \emph{$CemaNeigeLayers[[iLayer]]$Pliq } \tab [numeric] series of liquid precip. [mm/d] \cr
\emph{$CemaNeigeLayers[[iLayer]]$Psol } \tab [numeric] series of solid precip. [mm/d] \cr \emph{$CemaNeigeLayers[[iLayer]]$Psol } \tab [numeric] series of solid precip. [mm/d] \cr
\emph{$CemaNeigeLayers[[iLayer]]$SnowPack } \tab [numeric] series of snow pack [mm] \cr \emph{$CemaNeigeLayers[[iLayer]]$SnowPack } \tab [numeric] series of snow pack [mm] \cr
\emph{$CemaNeigeLayers[[iLayer]]$ThermalState } \tab [numeric] series of snow pack thermal state [°C] \cr \emph{$CemaNeigeLayers[[iLayer]]$ThermalState } \tab [numeric] series of snow pack thermal state [°C] \cr
\emph{$CemaNeigeLayers[[iLayer]]$Gratio } \tab [numeric] series of Gratio [0-1] \cr \emph{$CemaNeigeLayers[[iLayer]]$Gratio } \tab [numeric] series of Gratio [0-1] \cr
\emph{$CemaNeigeLayers[[iLayer]]$PotMelt } \tab [numeric] series of potential snow melt [mm/d] \cr \emph{$CemaNeigeLayers[[iLayer]]$PotMelt } \tab [numeric] series of potential snow melt [mm/d] \cr
\emph{$CemaNeigeLayers[[iLayer]]$Melt } \tab [numeric] series of actual snow melt [mm/d] \cr \emph{$CemaNeigeLayers[[iLayer]]$Melt } \tab [numeric] series of actual snow melt [mm/d] \cr
\emph{$CemaNeigeLayers[[iLayer]]$PliqAndMelt } \tab [numeric] series of liquid precip. + actual snow melt [mm/d] \cr \emph{$CemaNeigeLayers[[iLayer]]$PliqAndMelt } \tab [numeric] series of liquid precip. + actual snow melt [mm/d] \cr
\emph{$CemaNeigeLayers[[iLayer]]$Temp } \tab [numeric] series of air temperature [°C] \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{$CemaNeigeLayers[[iLayer]]$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{$CemaNeigeLayers[[iLayer]]$Glocalmax } \tab [numeric] series of local melt threshold for hysteresis [mm] \cr
\emph{$StateEnd} \tab [numeric] states at the end of the run: \cr\tab store & unit hydrographs levels [mm], CemaNeige states [mm & °C], \cr\tab see \code{\link{CreateIniStates}} for more details \cr \emph{$StateEnd} \tab [numeric] states at the end of the run: \cr\tab store & unit hydrographs levels [mm], CemaNeige states [mm & °C], \cr\tab 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) (refer to the provided references or to the package source code for further details on these model outputs)
} }
......
man/RunModel_CemaNeigeGR6J.Rd
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...@@ -36,41 +36,41 @@ CemaNeige X4 \tab (optional) percentage (between 0 and 1) of annual snowfall def ...@@ -36,41 +36,41 @@ CemaNeige X4 \tab (optional) percentage (between 0 and 1) of annual snowfall def
\value{ \value{
[list] list containing the function outputs organised as follows: [list] list containing the function outputs organised as follows:
\tabular{ll}{ \tabular{ll}{
\emph{$DatesR } \tab [POSIXlt] series of dates \cr \emph{$DatesR } \tab [POSIXlt] series of dates \cr
\emph{$PotEvap} \tab [numeric] series of input potential evapotranspiration [mm/d] \cr \emph{$PotEvap} \tab [numeric] series of input potential evapotranspiration [mm/d] \cr
\emph{$Precip } \tab [numeric] series of input total precipitation [mm/d] \cr \emph{$Precip } \tab [numeric] series of input total precipitation [mm/d] \cr
\emph{$Prod } \tab [numeric] series of production store level [mm] \cr \emph{$Prod } \tab [numeric] series of production store level [mm] \cr
\emph{$Pn } \tab [numeric] series of net rainfall [mm/d] \cr \emph{$Pn } \tab [numeric] series of net rainfall [mm/d] \cr
\emph{$Ps } \tab [numeric] series of the part of Ps filling the production store [mm/d] \cr \emph{$Ps } \tab [numeric] series of the part of Ps filling the production store [mm/d] \cr
\emph{$AE } \tab [numeric] series of actual evapotranspiration [mm/d] \cr \emph{$AE } \tab [numeric] series of actual evapotranspiration [mm/d] \cr
\emph{$Perc } \tab [numeric] series of percolation (PERC) [mm/d] \cr \emph{$Perc } \tab [numeric] series of percolation (PERC) [mm/d] \cr
\emph{$PR } \tab [numeric] series of PR=PN-PS+PERC [mm/d] \cr \emph{$PR } \tab [numeric] series of PR=PN-PS+PERC [mm/d] \cr
\emph{$Q9 } \tab [numeric] series of UH1 outflow (Q9) [mm/d] \cr \emph{$Q9 } \tab [numeric] series of UH1 outflow (Q9) [mm/d] \cr
\emph{$Q1 } \tab [numeric] series of UH2 outflow (Q1) [mm/d] \cr \emph{$Q1 } \tab [numeric] series of UH2 outflow (Q1) [mm/d] \cr
\emph{$Rout } \tab [numeric] series of routing store level [mm] \cr \emph{$Rout } \tab [numeric] series of routing store level [mm] \cr
\emph{$Exch } \tab [numeric] series of potential semi-exchange between catchments [mm/d] \cr \emph{$Exch } \tab [numeric] series of potential semi-exchange between catchments [mm/d] \cr
\emph{$AExch1 } \tab [numeric] series of actual exchange between catchments for branch 1 [mm/d] \cr \emph{$AExch1 } \tab [numeric] series of actual exchange between catchments for branch 1 [mm/d] \cr
\emph{$AExch2 } \tab [numeric] series of actual exchange between catchments for branch 2 [mm/d] \cr \emph{$AExch2 } \tab [numeric] series of actual exchange between catchments for branch 2 [mm/d] \cr
\emph{$AExch } \tab [numeric] series of actual exchange between catchments (1+2) [mm/d] \cr \emph{$AExch } \tab [numeric] series of actual exchange between catchments (1+2) [mm/d] \cr
\emph{$QR } \tab [numeric] series of routing store outflow (QR) [mm/d] \cr \emph{$QR } \tab [numeric] series of routing store outflow (QR) [mm/d] \cr
\emph{$QRExp } \tab [numeric] series of exponential store outflow (QRExp) [mm/d] \cr \emph{$QRExp } \tab [numeric] series of exponential store outflow (QRExp) [mm/d] \cr
\emph{$Exp } \tab [numeric] series of exponential store level (negative) [mm] \cr \emph{$Exp } \tab [numeric] series of exponential store level (negative) [mm] \cr
\emph{$QD } \tab [numeric] series of direct flow from UH2 after exchange (QD) [mm/d] \cr \emph{$QD } \tab [numeric] series of direct flow from UH2 after exchange (QD) [mm/d] \cr
\emph{$Qsim } \tab [numeric] series of Qsim [mm/d] \cr \emph{$Qsim } \tab [numeric] series of Qsim [mm/d] \cr
\emph{$CemaNeigeLayers} \tab [list] list of CemaNeige outputs (1 list per layer) \cr \emph{$CemaNeigeLayers} \tab [list] list of CemaNeige outputs (1 list per layer) \cr
\emph{$CemaNeigeLayers[[iLayer]]$Pliq } \tab [numeric] series of liquid precip. [mm/d] \cr \emph{$CemaNeigeLayers[[iLayer]]$Pliq } \tab [numeric] series of liquid precip. [mm/d] \cr
\emph{$CemaNeigeLayers[[iLayer]]$Psol } \tab [numeric] series of solid precip. [mm/d] \cr \emph{$CemaNeigeLayers[[iLayer]]$Psol } \tab [numeric] series of solid precip. [mm/d] \cr
\emph{$CemaNeigeLayers[[iLayer]]$SnowPack } \tab [numeric] series of snow pack [mm] \cr \emph{$CemaNeigeLayers[[iLayer]]$SnowPack } \tab [numeric] series of snow pack [mm] \cr
\emph{$CemaNeigeLayers[[iLayer]]$ThermalState } \tab [numeric] series of snow pack thermal state [°C] \cr \emph{$CemaNeigeLayers[[iLayer]]$ThermalState } \tab [numeric] series of snow pack thermal state [°C] \cr
\emph{$CemaNeigeLayers[[iLayer]]$Gratio } \tab [numeric] series of Gratio [0-1] \cr \emph{$CemaNeigeLayers[[iLayer]]$Gratio } \tab [numeric] series of Gratio [0-1] \cr
\emph{$CemaNeigeLayers[[iLayer]]$PotMelt } \tab [numeric] series of potential snow melt [mm/d] \cr \emph{$CemaNeigeLayers[[iLayer]]$PotMelt } \tab [numeric] series of potential snow melt [mm/d] \cr
\emph{$CemaNeigeLayers[[iLayer]]$Melt } \tab [numeric] series of actual snow melt [mm/d] \cr \emph{$CemaNeigeLayers[[iLayer]]$Melt } \tab [numeric] series of actual snow melt [mm/d] \cr
\emph{$CemaNeigeLayers[[iLayer]]$PliqAndMelt } \tab [numeric] series of liquid precip. + actual snow melt [mm/d] \cr \emph{$CemaNeigeLayers[[iLayer]]$PliqAndMelt } \tab [numeric] series of liquid precip. + actual snow melt [mm/d] \cr
\emph{$CemaNeigeLayers[[iLayer]]$Temp } \tab [numeric] series of air temperature [°C] \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{$CemaNeigeLayers[[iLayer]]$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{$CemaNeigeLayers[[iLayer]]$Glocalmax } \tab [numeric] series of local melt threshold for hysteresis [mm] \cr
\emph{$StateEnd} \tab [numeric] states at the end of the run: \cr\tab store & unit hydrographs levels [mm], CemaNeige states [mm & °C], \cr\tab see \code{\link{CreateIniStates}} for more details \cr \emph{$StateEnd} \tab [numeric] states at the end of the run: \cr\tab store & unit hydrographs levels [mm], CemaNeige states [mm & °C], \cr\tab 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) (refer to the provided references or to the package source code for further details on these model outputs)
} }
......
man/RunModel_GR1A.Rd
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...@@ -27,14 +27,14 @@ GR1A X1 \tab model parameter [-] \cr ...@@ -27,14 +27,14 @@ GR1A X1 \tab model parameter [-] \cr
\value{ \value{
[list] list containing the function outputs organised as follows: [list] list containing the function outputs organised as follows:
\tabular{ll}{ \tabular{ll}{
\emph{$DatesR } \tab [POSIXlt] series of dates \cr \emph{$DatesR } \tab [POSIXlt] series of dates \cr
\emph{$PotEvap } \tab [numeric] series of input potential evapotranspiration [mm/y] \cr \emph{$PotEvap } \tab [numeric] series of input potential evapotranspiration [mm/y] \cr
\emph{$Precip } \tab [numeric] series of input total precipitation [mm/y] \cr \emph{$Precip } \tab [numeric] series of input total precipitation [mm/y] \cr
\emph{$Qsim } \tab [numeric] series of simulated discharge [mm/y] \cr \emph{$Qsim } \tab [numeric] series of simulated discharge [mm/y] \cr
\emph{$StateEnd} \tab [numeric] states at the end of the run (NULL) [-] \cr \emph{$StateEnd} \tab [numeric] states at the end of the run (NULL) [-] \cr
} }
(refer to the provided references or to the package source code for further details on these model outputs) (refer to the provided references or to the package source code for further details on these model outputs)
} }
......
man/RunModel_GR2M.Rd
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...@@ -28,21 +28,21 @@ GR2M X2 \tab groundwater exchange coefficient [-] \cr ...@@ -28,21 +28,21 @@ GR2M X2 \tab groundwater exchange coefficient [-] \cr
\value{ \value{
[list] list containing the function outputs organised as follows: [list] list containing the function outputs organised as follows:
\tabular{ll}{ \tabular{ll}{
\emph{$DatesR } \tab [POSIXlt] series of dates \cr \emph{$DatesR } \tab [POSIXlt] series of dates \cr
\emph{$PotEvap } \tab [numeric] series of input potential evapotranspiration [mm/month] \cr \emph{$PotEvap } \tab [numeric] series of input potential evapotranspiration [mm/month] \cr
\emph{$Precip } \tab [numeric] series of input total precipitation [mm/month] \cr \emph{$Precip } \tab [numeric] series of input total precipitation [mm/month] \cr
\emph{$AE } \tab [numeric] series of actual evapotranspiration [mm/month] \cr \emph{$AE } \tab [numeric] series of actual evapotranspiration [mm/month] \cr
\emph{$Pn } \tab [numeric] series of net rainfall (P1) [mm/month] \cr \emph{$Pn } \tab [numeric] series of net rainfall (P1) [mm/month] \cr
\emph{$Perc } \tab [numeric] series of percolation (P2) [mm/month] \cr \emph{$Perc } \tab [numeric] series of percolation (P2) [mm/month] \cr
\emph{$PR } \tab [numeric] series of PR=Pn+Perc (P3) [mm/month] \cr \emph{$PR } \tab [numeric] series of PR=Pn+Perc (P3) [mm/month] \cr
\emph{$Exch } \tab [numeric] series of potential exchange between catchments [mm/month] \cr \emph{$Exch } \tab [numeric] series of potential exchange between catchments [mm/month] \cr
\emph{$Prod } \tab [numeric] series of production store level [mm] \cr \emph{$Prod } \tab [numeric] series of production store level [mm] \cr
\emph{$Rout } \tab [numeric] series of routing store level [mm] \cr \emph{$Rout } \tab [numeric] series of routing store level [mm] \cr
\emph{$Qsim } \tab [numeric] series of simulated discharge [mm/month] \cr \emph{$Qsim } \tab [numeric] series of simulated discharge [mm/month] \cr
\emph{$StateEnd} \tab [numeric] states at the end of the run (production store level and routing store level) [mm], \cr\tab see \code{\link{CreateIniStates}} for more details \cr \emph{$StateEnd} \tab [numeric] states at the end of the run (production store level and routing store level) [mm], \cr\tab 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) (refer to the provided references or to the package source code for further details on these model outputs)
} }
......
man/RunModel_GR4H.Rd
+ 25
25
View file @ 68007cd4
...@@ -19,36 +19,36 @@ RunModel_GR4H(InputsModel, RunOptions, Param) ...@@ -19,36 +19,36 @@ RunModel_GR4H(InputsModel, RunOptions, Param)
\item{RunOptions}{[object of class \emph{RunOptions}] see \code{\link{CreateRunOptions}} for details} \item{RunOptions}{[object of class \emph{RunOptions}] see \code{\link{CreateRunOptions}} for details}
\item{Param}{[numeric] vector of 4 parameters \item{Param}{[numeric] vector of 4 parameters
\tabular{ll}{ \tabular{ll}{
GR4H X1 \tab production store capacity [mm] \cr GR4H X1 \tab production store capacity [mm] \cr
GR4H X2 \tab groundwater exchange coefficient [mm/h] \cr GR4H X2 \tab groundwater exchange coefficient [mm/h] \cr
GR4H X3 \tab routing store capacity [mm] \cr GR4H X3 \tab routing store capacity [mm] \cr
GR4H X4 \tab unit hydrograph time constant [h] \cr GR4H X4 \tab unit hydrograph time constant [h] \cr
}} }}
} }
\value{ \value{
[list] list containing the function outputs organised as follows: [list] list containing the function outputs organised as follows:
\tabular{ll}{ \tabular{ll}{
\emph{$DatesR } \tab [POSIXlt] series of dates \cr \emph{$DatesR } \tab [POSIXlt] series of dates \cr
\emph{$PotEvap } \tab [numeric] series of input potential evapotranspiration [mm/h] \cr \emph{$PotEvap } \tab [numeric] series of input potential evapotranspiration [mm/h] \cr
\emph{$Precip } \tab [numeric] series of input total precipitation [mm/h] \cr \emph{$Precip } \tab [numeric] series of input total precipitation [mm/h] \cr
\emph{$Prod } \tab [numeric] series of production store level [mm] \cr \emph{$Prod } \tab [numeric] series of production store level [mm] \cr
\emph{$AE } \tab [numeric] series of actual evapotranspiration [mm/h] \cr \emph{$AE } \tab [numeric] series of actual evapotranspiration [mm/h] \cr
\emph{$Perc } \tab [numeric] series of percolation (PERC) [mm/h] \cr \emph{$Perc } \tab [numeric] series of percolation (PERC) [mm/h] \cr
\emph{$PR } \tab [numeric] series of PR=Pn-Ps+Perc [mm/h] \cr \emph{$PR } \tab [numeric] series of PR=Pn-Ps+Perc [mm/h] \cr
\emph{$Q9 } \tab [numeric] series of UH1 outflow (Q9) [mm/h] \cr \emph{$Q9 } \tab [numeric] series of UH1 outflow (Q9) [mm/h] \cr
\emph{$Q1 } \tab [numeric] series of UH2 outflow (Q1) [mm/h] \cr \emph{$Q1 } \tab [numeric] series of UH2 outflow (Q1) [mm/h] \cr
\emph{$Rout } \tab [numeric] series of routing store level [mm] \cr \emph{$Rout } \tab [numeric] series of routing store level [mm] \cr
\emph{$Exch } \tab [numeric] series of potential semi-exchange between catchments [mm/h] \cr \emph{$Exch } \tab [numeric] series of potential semi-exchange between catchments [mm/h] \cr
\emph{$AExch } \tab [numeric] series of actual exchange between catchments (1+2) [mm/h] \cr \emph{$AExch } \tab [numeric] series of actual exchange between catchments (1+2) [mm/h] \cr
\emph{$QR } \tab [numeric] series of routing store outflow (QR) [mm/h] \cr \emph{$QR } \tab [numeric] series of routing store outflow (QR) [mm/h] \cr
\emph{$QD } \tab [numeric] series of direct flow from UH2 after exchange (QD) [mm/h] \cr \emph{$QD } \tab [numeric] series of direct flow from UH2 after exchange (QD) [mm/h] \cr
\emph{$Qsim } \tab [numeric] series of simulated discharge [mm/h] \cr \emph{$Qsim } \tab [numeric] series of simulated discharge [mm/h] \cr
\emph{$StateEnd} \tab [numeric] states at the end of the run (res. levels, UH1 levels, UH2 levels) [mm], see \code{\link{CreateIniStates}} for more details \cr \emph{$StateEnd} \tab [numeric] states at the end of the run (res. levels, UH1 levels, UH2 levels) [mm], 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) (refer to the provided references or to the package source code for further details on these model outputs)
} }
......
man/RunModel_GR4J.Rd
+ 27
27
View file @ 68007cd4
...@@ -19,38 +19,38 @@ RunModel_GR4J(InputsModel, RunOptions, Param) ...@@ -19,38 +19,38 @@ RunModel_GR4J(InputsModel, RunOptions, Param)
\item{RunOptions}{[object of class \emph{RunOptions}] see \code{\link{CreateRunOptions}} for details} \item{RunOptions}{[object of class \emph{RunOptions}] see \code{\link{CreateRunOptions}} for details}
\item{Param}{[numeric] vector of 4 parameters \item{Param}{[numeric] vector of 4 parameters
\tabular{ll}{ \tabular{ll}{
GR4J X1 \tab production store capacity [mm] \cr GR4J X1 \tab production store capacity [mm] \cr
GR4J X2 \tab intercatchment exchange coefficient [mm/d] \cr GR4J X2 \tab intercatchment exchange coefficient [mm/d] \cr
GR4J X3 \tab routing store capacity [mm] \cr GR4J X3 \tab routing store capacity [mm] \cr
GR4J X4 \tab unit hydrograph time constant [d] \cr GR4J X4 \tab unit hydrograph time constant [d] \cr
}} }}
} }
\value{ \value{
[list] list containing the function outputs organised as follows: [list] list containing the function outputs organised as follows:
\tabular{ll}{ \tabular{ll}{
\emph{$DatesR } \tab [POSIXlt] series of dates \cr \emph{$DatesR } \tab [POSIXlt] series of dates \cr
\emph{$PotEvap } \tab [numeric] series of input potential evapotranspiration [mm/d] \cr \emph{$PotEvap } \tab [numeric] series of input potential evapotranspiration [mm/d] \cr
\emph{$Precip } \tab [numeric] series of input total precipitation [mm/d] \cr \emph{$Precip } \tab [numeric] series of input total precipitation [mm/d] \cr
\emph{$Prod } \tab [numeric] series of production store level [mm] \cr \emph{$Prod } \tab [numeric] series of production store level [mm] \cr
\emph{$Pn } \tab [numeric] series of net rainfall [mm/d] \cr \emph{$Pn } \tab [numeric] series of net rainfall [mm/d] \cr
\emph{$Ps } \tab [numeric] series of the part of Pn filling the production store [mm/d] \cr \emph{$Ps } \tab [numeric] series of the part of Pn filling the production store [mm/d] \cr
\emph{$AE } \tab [numeric] series of actual evapotranspiration [mm/d] \cr \emph{$AE } \tab [numeric] series of actual evapotranspiration [mm/d] \cr
\emph{$Perc } \tab [numeric] series of percolation (PERC) [mm/d] \cr \emph{$Perc } \tab [numeric] series of percolation (PERC) [mm/d] \cr
\emph{$PR } \tab [numeric] series of PR=Pn-Ps+Perc [mm/d] \cr \emph{$PR } \tab [numeric] series of PR=Pn-Ps+Perc [mm/d] \cr
\emph{$Q9 } \tab [numeric] series of UH1 outflow (Q9) [mm/d] \cr \emph{$Q9 } \tab [numeric] series of UH1 outflow (Q9) [mm/d] \cr
\emph{$Q1 } \tab [numeric] series of UH2 outflow (Q1) [mm/d] \cr \emph{$Q1 } \tab [numeric] series of UH2 outflow (Q1) [mm/d] \cr
\emph{$Rout } \tab [numeric] series of routing store level [mm] \cr \emph{$Rout } \tab [numeric] series of routing store level [mm] \cr
\emph{$Exch } \tab [numeric] series of potential semi-exchange between catchments [mm/d] \cr \emph{$Exch } \tab [numeric] series of potential semi-exchange between catchments [mm/d] \cr
\emph{$AExch1 } \tab [numeric] series of actual exchange between catchments for branch 1 [mm/d] \cr \emph{$AExch1 } \tab [numeric] series of actual exchange between catchments for branch 1 [mm/d] \cr
\emph{$AExch2 } \tab [numeric] series of actual exchange between catchments for branch 2 [mm/d] \cr \emph{$AExch2 } \tab [numeric] series of actual exchange between catchments for branch 2 [mm/d] \cr
\emph{$AExch } \tab [numeric] series of actual exchange between catchments (1+2) [mm/d] \cr \emph{$AExch } \tab [numeric] series of actual exchange between catchments (1+2) [mm/d] \cr
\emph{$QR } \tab [numeric] series of routing store outflow (QR) [mm/d] \cr \emph{$QR } \tab [numeric] series of routing store outflow (QR) [mm/d] \cr
\emph{$QD } \tab [numeric] series of direct flow from UH2 after exchange (QD) [mm/d] \cr \emph{$QD } \tab [numeric] series of direct flow from UH2 after exchange (QD) [mm/d] \cr
\emph{$Qsim } \tab [numeric] series of simulated discharge [mm/d] \cr \emph{$Qsim } \tab [numeric] series of simulated discharge [mm/d] \cr
\emph{$StateEnd} \tab [numeric] states at the end of the run (res. levels, UH1 levels, UH2 levels) [mm], \cr\tab see \code{\link{CreateIniStates}} for more details \cr \emph{$StateEnd} \tab [numeric] states at the end of the run (res. levels, UH1 levels, UH2 levels) [mm], \cr\tab 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) (refer to the provided references or to the package source code for further details on these model outputs)
} }
......
man/RunModel_GR5J.Rd
+ 30
30
View file @ 68007cd4
...@@ -19,41 +19,41 @@ RunModel_GR5J(InputsModel, RunOptions, Param) ...@@ -19,41 +19,41 @@ RunModel_GR5J(InputsModel, RunOptions, Param)
\item{RunOptions}{[object of class \emph{RunOptions}] see \code{\link{CreateRunOptions}} for details} \item{RunOptions}{[object of class \emph{RunOptions}] see \code{\link{CreateRunOptions}} for details}
\item{Param}{[numeric] vector of 5 parameters \item{Param}{[numeric] vector of 5 parameters
\tabular{ll}{ \tabular{ll}{
GR5J X1 \tab production store capacity [mm] \cr GR5J X1 \tab production store capacity [mm] \cr
GR5J X2 \tab intercatchment exchange coefficient [mm/d] \cr GR5J X2 \tab intercatchment exchange coefficient [mm/d] \cr
GR5J X3 \tab routing store capacity [mm] \cr GR5J X3 \tab routing store capacity [mm] \cr
GR5J X4 \tab unit hydrograph time constant [d] \cr GR5J X4 \tab unit hydrograph time constant [d] \cr
GR5J X5 \tab intercatchment exchange threshold [-] \cr GR5J X5 \tab intercatchment exchange threshold [-] \cr
}} }}
} }
\value{ \value{
[list] list containing the function outputs organised as follows: [list] list containing the function outputs organised as follows:
\tabular{ll}{ \tabular{ll}{
\emph{$DatesR } \tab [POSIXlt] series of dates \cr \emph{$DatesR } \tab [POSIXlt] series of dates \cr
\emph{$PotEvap } \tab [numeric] series of input potential evapotranspiration [mm/d] \cr \emph{$PotEvap } \tab [numeric] series of input potential evapotranspiration [mm/d] \cr
\emph{$Precip } \tab [numeric] series of input total precipitation [mm/d] \cr \emph{$Precip } \tab [numeric] series of input total precipitation [mm/d] \cr
\emph{$Prod } \tab [numeric] series of production store level [mm] \cr \emph{$Prod } \tab [numeric] series of production store level [mm] \cr
\emph{$Pn } \tab [numeric] series of net rainfall [mm/d] \cr \emph{$Pn } \tab [numeric] series of net rainfall [mm/d] \cr
\emph{$Ps } \tab [numeric] series of the part of Pn filling the production store [mm/d] \cr \emph{$Ps } \tab [numeric] series of the part of Pn filling the production store [mm/d] \cr
\emph{$AE } \tab [numeric] series of actual evapotranspiration [mm/d] \cr \emph{$AE } \tab [numeric] series of actual evapotranspiration [mm/d] \cr
\emph{$Perc } \tab [numeric] series of percolation (PERC) [mm/d] \cr \emph{$Perc } \tab [numeric] series of percolation (PERC) [mm/d] \cr
\emph{$PR } \tab [numeric] series of PR=Pn-Ps+Perc [mm/d] \cr \emph{$PR } \tab [numeric] series of PR=Pn-Ps+Perc [mm/d] \cr
\emph{$Q9 } \tab [numeric] series of UH1 outflow (Q9) [mm/d] \cr \emph{$Q9 } \tab [numeric] series of UH1 outflow (Q9) [mm/d] \cr
\emph{$Q1 } \tab [numeric] series of UH2 outflow (Q1) [mm/d] \cr \emph{$Q1 } \tab [numeric] series of UH2 outflow (Q1) [mm/d] \cr
\emph{$Rout } \tab [numeric] series of routing store level [mm] \cr \emph{$Rout } \tab [numeric] series of routing store level [mm] \cr
\emph{$Exch } \tab [numeric] series of potential semi-exchange between catchments [mm/d] \cr \emph{$Exch } \tab [numeric] series of potential semi-exchange between catchments [mm/d] \cr
\emph{$AExch1 } \tab [numeric] series of actual exchange between catchments for branch 1 [mm/d] \cr \emph{$AExch1 } \tab [numeric] series of actual exchange between catchments for branch 1 [mm/d] \cr
\emph{$AExch2 } \tab [numeric] series of actual exchange between catchments for branch 2 [mm/d] \cr \emph{$AExch2 } \tab [numeric] series of actual exchange between catchments for branch 2 [mm/d] \cr
\emph{$AExch } \tab [numeric] series of actual exchange between catchments (1+2) [mm/d] \cr \emph{$AExch } \tab [numeric] series of actual exchange between catchments (1+2) [mm/d] \cr
\emph{$QR } \tab [numeric] series of routing store outflow (QR) [mm/d] \cr \emph{$QR } \tab [numeric] series of routing store outflow (QR) [mm/d] \cr
\emph{$QD } \tab [numeric] series of direct flow from UH2 after exchange (QD) [mm/d] \cr \emph{$QD } \tab [numeric] series of direct flow from UH2 after exchange (QD) [mm/d] \cr
\emph{$Qsim } \tab [numeric] series of simulated discharge [mm/d] \cr \emph{$Qsim } \tab [numeric] series of simulated discharge [mm/d] \cr
\emph{$StateEnd} \tab [numeric] states at the end of the run (res. levels, UH1 levels, UH2 levels) [mm], \cr\tab see \code{\link{CreateIniStates}} for more details \cr \emph{$StateEnd} \tab [numeric] states at the end of the run (res. levels, UH1 levels, UH2 levels) [mm], \cr\tab 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) (refer to the provided references or to the package source code for further details on these model outputs)
} }
......
man/RunModel_GR6J.Rd
+ 33
33
View file @ 68007cd4
...@@ -19,44 +19,44 @@ RunModel_GR6J(InputsModel, RunOptions, Param) ...@@ -19,44 +19,44 @@ RunModel_GR6J(InputsModel, RunOptions, Param)
\item{RunOptions}{[object of class \emph{RunOptions}] see \code{\link{CreateRunOptions}} for details} \item{RunOptions}{[object of class \emph{RunOptions}] see \code{\link{CreateRunOptions}} for details}
\item{Param}{[numeric] vector of 6 parameters \item{Param}{[numeric] vector of 6 parameters
\tabular{ll}{ \tabular{ll}{
GR6J X1 \tab production store capacity [mm] \cr GR6J X1 \tab production store capacity [mm] \cr
GR6J X2 \tab intercatchment exchange coefficient [mm/d] \cr GR6J X2 \tab intercatchment exchange coefficient [mm/d] \cr
GR6J X3 \tab routing store capacity [mm] \cr GR6J X3 \tab routing store capacity [mm] \cr
GR6J X4 \tab unit hydrograph time constant [d] \cr GR6J X4 \tab unit hydrograph time constant [d] \cr
GR6J X5 \tab intercatchment exchange threshold [-] \cr GR6J X5 \tab intercatchment exchange threshold [-] \cr
GR6J X6 \tab coefficient for emptying exponential store [mm] \cr GR6J X6 \tab coefficient for emptying exponential store [mm] \cr
}} }}
} }
\value{ \value{
[list] list containing the function outputs organised as follows: [list] list containing the function outputs organised as follows:
\tabular{ll}{ \tabular{ll}{
\emph{$DatesR } \tab [POSIXlt] series of dates \cr \emph{$DatesR } \tab [POSIXlt] series of dates \cr
\emph{$PotEvap } \tab [numeric] series of input potential evapotranspiration [mm/d] \cr \emph{$PotEvap } \tab [numeric] series of input potential evapotranspiration [mm/d] \cr
\emph{$Precip } \tab [numeric] series of input total precipitation [mm/d] \cr \emph{$Precip } \tab [numeric] series of input total precipitation [mm/d] \cr
\emph{$Prod } \tab [numeric] series of production store level [mm] \cr \emph{$Prod } \tab [numeric] series of production store level [mm] \cr
\emph{$Pn } \tab [numeric] series of net rainfall [mm/d] \cr \emph{$Pn } \tab [numeric] series of net rainfall [mm/d] \cr
\emph{$Ps } \tab [numeric] series of the part of Pn filling the production store [mm/d] \cr \emph{$Ps } \tab [numeric] series of the part of Pn filling the production store [mm/d] \cr
\emph{$AE } \tab [numeric] series of actual evapotranspiration [mm/d] \cr \emph{$AE } \tab [numeric] series of actual evapotranspiration [mm/d] \cr
\emph{$Perc } \tab [numeric] series of percolation (PERC) [mm/d] \cr \emph{$Perc } \tab [numeric] series of percolation (PERC) [mm/d] \cr
\emph{$PR } \tab [numeric] series of PR=Pn-Ps+Perc [mm/d] \cr \emph{$PR } \tab [numeric] series of PR=Pn-Ps+Perc [mm/d] \cr
\emph{$Q9 } \tab [numeric] series of UH1 outflow (Q9) [mm/d] \cr \emph{$Q9 } \tab [numeric] series of UH1 outflow (Q9) [mm/d] \cr
\emph{$Q1 } \tab [numeric] series of UH2 outflow (Q1) [mm/d] \cr \emph{$Q1 } \tab [numeric] series of UH2 outflow (Q1) [mm/d] \cr
\emph{$Rout } \tab [numeric] series of routing store level [mm] \cr \emph{$Rout } \tab [numeric] series of routing store level [mm] \cr
\emph{$Exch } \tab [numeric] series of potential semi-exchange between catchments [mm/d] \cr \emph{$Exch } \tab [numeric] series of potential semi-exchange between catchments [mm/d] \cr
\emph{$AExch1 } \tab [numeric] series of actual exchange between catchments for branch 1 [mm/d] \cr \emph{$AExch1 } \tab [numeric] series of actual exchange between catchments for branch 1 [mm/d] \cr
\emph{$AExch2 } \tab [numeric] series of actual exchange between catchments for branch 2 [mm/d] \cr \emph{$AExch2 } \tab [numeric] series of actual exchange between catchments for branch 2 [mm/d] \cr
\emph{$AExch } \tab [numeric] series of actual exchange between catchments (1+2) [mm/d] \cr \emph{$AExch } \tab [numeric] series of actual exchange between catchments (1+2) [mm/d] \cr
\emph{$QR } \tab [numeric] series of routing store outflow (QR) [mm/d] \cr \emph{$QR } \tab [numeric] series of routing store outflow (QR) [mm/d] \cr
\emph{$QRExp } \tab [numeric] series of exponential store outflow (QRExp) [mm/d] \cr \emph{$QRExp } \tab [numeric] series of exponential store outflow (QRExp) [mm/d] \cr
\emph{$Exp } \tab [numeric] series of exponential store level (negative) [mm] \cr \emph{$Exp } \tab [numeric] series of exponential store level (negative) [mm] \cr
\emph{$QD } \tab [numeric] series of direct flow from UH2 after exchange (QD) [mm/d] \cr \emph{$QD } \tab [numeric] series of direct flow from UH2 after exchange (QD) [mm/d] \cr
\emph{$Qsim } \tab [numeric] series of Qsim [mm/d] \cr \emph{$Qsim } \tab [numeric] series of Qsim [mm/d] \cr
\emph{$StateEnd} \tab [numeric] states at the end of the run (res. levels, UH1 levels, UH2 levels) [mm], \cr\tab see \code{\link{CreateIniStates}} for more details \cr \emph{$StateEnd} \tab [numeric] states at the end of the run (res. levels, UH1 levels, UH2 levels) [mm], \cr\tab 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) (refer to the provided references or to the package source code for further details on these model outputs)
} }
......
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