This vignette provides an overview
of the basic modelling workflow with the RPhosFate
package.
Load the package and obtain a copy of the demonstration project:
Use RPhosFate()
or catchment()
to
initialise the project:
firstRun()
calls all low-level interface methods for the
specified substance in the required order:
Snap coordinates of provided calibration gauges to the respective midpoint of the nearest channel cell if necessary and check calibration quality:
SS is calibrated by iteratively specifying better parameter values
for ns_dep_ovl
(overland deposition rate) and/or
ns_dep_cha
(channel deposition rate) as well as calling
subsequentRun()
for SS afterwards until pleased with the
metrics. By default, subsequentRun()
only calls the
transport()
low-level interface method for the specified
substance:
x <- setParameter(x, ns_dep_ovl = 15e-4)
x <- subsequentRun(x, substance = "SS")
metrics <- calibrationQuality(x, substance = "SS", col = "SS_load")
The autoCalibrate()
and autoCalibrate2()
methods may provide more comfortable alternatives to this process.
First, a further call to subsequentRun()
for PP is
necessary:
Same procedure as with SS apart from iteratively specifying better parameter values for the enrichment ratio:
x <- setParameter(x, nv_enr_rto = c(PP = 1.4))
x <- subsequentRun(x, substance = "PP")
metrics <- calibrationQuality(x, substance = "PP", col = "PP_load")
In case the only substance of interest is PP, it is possible to set
its enrichment ratio to one and directly calibrate it via
ns_dep_ovl
and/or ns_dep_cha
.