The hardware and bandwidth for this mirror is donated by METANET, the Webhosting and Full Service-Cloud Provider.
If you wish to report a bug, or if you are interested in having us mirror your free-software or open-source project, please feel free to contact us at mirror[@]metanet.ch.
The ofpetrial
package allows the user to design agronomic input experiments in a reproducible manner without using ArcGIS or QGIS. The vignette for this package provides more detailed guidance on how to use the package.
You can install the CRAN version of the ofpetrial
package.
You can install the development version of ofpetrial from Github:
Here, we demonstrate how to use the ofpetrial
package to create a single-input on-farm experiment trial design (more detailed instructions on the basic workflow is provided in this article).
We start with specifying plot and machine information for inputs using prep_plot
.
n_plot_info <-
prep_plot(
input_name = "NH3",
unit_system = "imperial",
machine_width = 30,
section_num = 1,
harvester_width = 30,
plot_width = 30
)
#>
Now, we can create experiment plots based on them using make_exp_plots()
.
exp_data <-
make_exp_plots(
input_plot_info = n_plot_info,
boundary_data = system.file("extdata", "boundary-simple1.shp", package = "ofpetrial"),
abline_data = system.file("extdata", "ab-line-simple1.shp", package = "ofpetrial"),
abline_type = "free"
)
viz(exp_data, type = "layout", abline = TRUE)
We first prepare nitrogen rates.
#!===========================================================
# ! Assign rates
# !===========================================================
n_rate_info <-
prep_rate(
plot_info = n_plot_info,
gc_rate = 180,
unit = "lb",
rates = c(100, 140, 180, 220, 260),
design_type = "ls",
rank_seq_ws = c(5, 4, 3, 2, 1)
)
dplyr::glimpse(n_rate_info)
#> Rows: 1
#> Columns: 12
#> $ input_name [3m[38;5;246m<chr>[39m[23m "NH3"
#> $ design_type [3m[38;5;246m<chr>[39m[23m "ls"
#> $ gc_rate [3m[38;5;246m<dbl>[39m[23m 180
#> $ unit [3m[38;5;246m<chr>[39m[23m "lb"
#> $ tgt_rate_original [3m[38;5;246m<list>[39m[23m <100, 140, 180, 220, 260>
#> $ tgt_rate_equiv [3m[38;5;246m<list>[39m[23m <82.0, 114.8, 147.6, 180.4, 213.2>
#> $ min_rate [3m[38;5;246m<lgl>[39m[23m NA
#> $ max_rate [3m[38;5;246m<lgl>[39m[23m NA
#> $ num_rates [3m[38;5;246m<int>[39m[23m 5
#> $ rank_seq_ws [3m[38;5;246m<list>[39m[23m <5, 4, 3, 2, 1>
#> $ rank_seq_as [3m[38;5;246m<list>[39m[23m <NULL>
#> $ rate_jump_threshold [3m[38;5;246m<lgl>[39m[23m NA
We can now use assign_rates()
to assign rates to experiment plots.
Here is the visualization of the trial design done by viz
.
Along with the spatial pattern of the input rates, the applicator/planter ab-line and harvester ab-line are drawn by default.
You can write out the trial design as a shape file.
This project was funded in part by a United States Department of Agriculture—National Institute of Food and Agriculture (USDA—NIFA) Food Security Program Grant (Award Number 2016-68004-24769) and by United States Department of Agriculture (USDA) -Natural Resources Conservation Service (NRCS), Commodity Credit Corporation (CCC), Conservation Innovation Grants On-Farm Conservation Innovation Trials (Award Number USDA-NRCS-NHQ-CIGOFT-20-GEN0010750).
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.