eval_n_summary: Evaluate number of planning units selected by solution
In prioritizr: Systematic Conservation Prioritization in R
View source: R/eval_n_summary.R
eval_n_summary R Documentation
Evaluate number of planning units selected by solution
Description
Calculate the number of planning units selected within a solution
to a conservation planning problem.
Usage
eval_n_summary(x, solution)
Arguments
x
problem() object.
solution
numeric, matrix, data.frame,
terra::rast(), or sf::sf() object.
The argument should be in the same format as the planning unit cost
data in the argument to x.
See the Solution format section for more information.
Details
This summary statistic is calculated as the sum of the values in
the solution. As a consequence, this metric can produce a
non-integer value (e.g., 4.3) for solutions containing proportion values
(e.g., generated by solving a problem() built using the
add_proportion_decisions() function).
Value
A tibble::tibble() object containing the number of planning
units selected within a solution.
It contains the following columns:
- summary
character description of the summary statistic.
The statistic associated with the "overall" value
in this column is calculated using the entire solution
(including all management zones if there are multiple zones).
If multiple management zones are present, then summary statistics
are also provided for each zone separately
(indicated using zone names).
- n
numeric number of selected planning units.
Solution format
Broadly speaking, the argument to solution must be in the same format as
the planning unit data in the argument to x.
Further details on the correct format are listed separately
for each of the different planning unit data formats:
x has numeric planning unitsThe argument to solution must be a
numeric vector with each element corresponding to a different planning
unit. It should have the same number of planning units as those
in the argument to x. Additionally, any planning units missing
cost (NA) values should also have missing (NA) values in the
argument to solution.
x has matrix planning unitsThe argument to solution must be a
matrix vector with each row corresponding to a different planning
unit, and each column correspond to a different management zone.
It should have the same number of planning units and zones
as those in the argument to x. Additionally, any planning units
missing cost (NA) values for a particular zone should also have a
missing (NA) values in the argument to solution.
x has terra::rast() planning unitsThe argument to solution
be a terra::rast() object where different grid cells (pixels) correspond
to different planning units and layers correspond to
a different management zones. It should have the same dimensionality
(rows, columns, layers), resolution, extent, and coordinate reference
system as the planning units in the argument to x. Additionally,
any planning units missing cost (NA) values for a particular zone
should also have missing (NA) values in the argument to solution.
x has data.frame planning unitsThe argument to solution must
be a data.frame with each column corresponding to a different zone,
each row corresponding to a different planning unit, and cell values
corresponding to the solution value. This means that if a data.frame
object containing the solution also contains additional columns, then
these columns will need to be subsetted prior to using this function
(see below for example with sf::sf() data).
Additionally, any planning units missing cost
(NA) values for a particular zone should also have missing (NA)
values in the argument to solution.
x has sf::sf() planning unitsThe argument to solution must be
a sf::sf() object with each column corresponding to a different
zone, each row corresponding to a different planning unit, and cell values
corresponding to the solution value. This means that if the
sf::sf() object containing the solution also contains additional
columns, then these columns will need to be subsetted prior to using this
function (see below for example).
Additionally, the argument to solution must also have the same
coordinate reference system as the planning unit data.
Furthermore, any planning units missing cost
(NA) values for a particular zone should also have missing (NA)
values in the argument to solution.
See Also
See summaries for an overview of all functions for summarizing solutions.
Other summaries:
eval_asym_connectivity_summary(),
eval_boundary_summary(),
eval_connectivity_summary(),
eval_cost_summary(),
eval_feature_representation_summary(),
eval_target_coverage_summary()
Examples
## Not run:
# set seed for reproducibility
set.seed(500)
# load data
sim_pu_raster <- get_sim_pu_raster()
sim_pu_polygons <- get_sim_pu_polygons()
sim_features <- get_sim_features()
sim_zones_pu_polygons <- get_sim_zones_pu_polygons()
sim_zones_features <- get_sim_zones_features()
# build minimal conservation problem with raster data
p1 <-
problem(sim_pu_raster, sim_features) %>%
add_min_set_objective() %>%
add_relative_targets(0.1) %>%
add_binary_decisions() %>%
add_default_solver(verbose = FALSE)
# solve the problem
s1 <- solve(p1)
# print solution
print(s1)
# plot solution
plot(s1, main = "solution", axes = FALSE)
# calculate number of selected planning units within solution
r1 <- eval_n_summary(p1, s1)
print(r1)
# build minimal conservation problem with polygon data
p2 <-
problem(sim_pu_polygons, sim_features, cost_column = "cost") %>%
add_min_set_objective() %>%
add_relative_targets(0.1) %>%
add_binary_decisions() %>%
add_default_solver(verbose = FALSE)
# solve the problem
s2 <- solve(p2)
# plot solution
plot(s2[, "solution_1"])
# print solution
print(s2)
# calculate number of selected planning units within solution
r2 <- eval_n_summary(p2, s2[, "solution_1"])
print(r2)
# manually calculate number of selected planning units
r2_manual <- sum(s2$solution_1, na.rm = TRUE)
print(r2_manual)
# build multi-zone conservation problem with polygon data
p3 <-
problem(
sim_zones_pu_polygons, sim_zones_features,
cost_column = c("cost_1", "cost_2", "cost_3")
) %>%
add_min_set_objective() %>%
add_relative_targets(matrix(runif(15, 0.1, 0.2), nrow = 5, ncol = 3)) %>%
add_binary_decisions() %>%
add_default_solver(verbose = FALSE)
# solve the problem
s3 <- solve(p3)
# print solution
print(s3)
# create new column representing the zone id that each planning unit
# was allocated to in the solution
s3$solution <- category_vector(
s3[, c("solution_1_zone_1", "solution_1_zone_2", "solution_1_zone_3")]
)
s3$solution <- factor(s3$solution)
# plot solution
plot(s3[, "solution"])
# calculate number of selected planning units within solution
r3 <- eval_n_summary(
p3, s3[, c("solution_1_zone_1", "solution_1_zone_2", "solution_1_zone_3")]
)
print(r3)
## End(Not run)
prioritizr documentation built on Aug. 9, 2023, 1:06 a.m.
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View source: R/eval_n_summary.R
| eval_n_summary | R Documentation |
Evaluate number of planning units selected by solution
Description
Calculate the number of planning units selected within a solution to a conservation planning problem.
Usage
eval_n_summary(x, solution)
Arguments
x |
|
solution |
|
Details
This summary statistic is calculated as the sum of the values in
the solution. As a consequence, this metric can produce a
non-integer value (e.g., 4.3) for solutions containing proportion values
(e.g., generated by solving a problem() built using the
add_proportion_decisions() function).
Value
A tibble::tibble() object containing the number of planning
units selected within a solution.
It contains the following columns:
- summary
characterdescription of the summary statistic. The statistic associated with the"overall"value in this column is calculated using the entire solution (including all management zones if there are multiple zones). If multiple management zones are present, then summary statistics are also provided for each zone separately (indicated using zone names).- n
numericnumber of selected planning units.
Solution format
Broadly speaking, the argument to solution must be in the same format as
the planning unit data in the argument to x.
Further details on the correct format are listed separately
for each of the different planning unit data formats:
xhasnumericplanning unitsThe argument to
solutionmust be anumericvector with each element corresponding to a different planning unit. It should have the same number of planning units as those in the argument tox. Additionally, any planning units missing cost (NA) values should also have missing (NA) values in the argument tosolution.xhasmatrixplanning unitsThe argument to
solutionmust be amatrixvector with each row corresponding to a different planning unit, and each column correspond to a different management zone. It should have the same number of planning units and zones as those in the argument tox. Additionally, any planning units missing cost (NA) values for a particular zone should also have a missing (NA) values in the argument tosolution.xhasterra::rast()planning unitsThe argument to
solutionbe aterra::rast()object where different grid cells (pixels) correspond to different planning units and layers correspond to a different management zones. It should have the same dimensionality (rows, columns, layers), resolution, extent, and coordinate reference system as the planning units in the argument tox. Additionally, any planning units missing cost (NA) values for a particular zone should also have missing (NA) values in the argument tosolution.xhasdata.frameplanning unitsThe argument to
solutionmust be adata.framewith each column corresponding to a different zone, each row corresponding to a different planning unit, and cell values corresponding to the solution value. This means that if adata.frameobject containing the solution also contains additional columns, then these columns will need to be subsetted prior to using this function (see below for example withsf::sf()data). Additionally, any planning units missing cost (NA) values for a particular zone should also have missing (NA) values in the argument tosolution.xhassf::sf()planning unitsThe argument to
solutionmust be asf::sf()object with each column corresponding to a different zone, each row corresponding to a different planning unit, and cell values corresponding to the solution value. This means that if thesf::sf()object containing the solution also contains additional columns, then these columns will need to be subsetted prior to using this function (see below for example). Additionally, the argument tosolutionmust also have the same coordinate reference system as the planning unit data. Furthermore, any planning units missing cost (NA) values for a particular zone should also have missing (NA) values in the argument tosolution.
See Also
See summaries for an overview of all functions for summarizing solutions.
Other summaries:
eval_asym_connectivity_summary(),
eval_boundary_summary(),
eval_connectivity_summary(),
eval_cost_summary(),
eval_feature_representation_summary(),
eval_target_coverage_summary()
Examples
## Not run:
# set seed for reproducibility
set.seed(500)
# load data
sim_pu_raster <- get_sim_pu_raster()
sim_pu_polygons <- get_sim_pu_polygons()
sim_features <- get_sim_features()
sim_zones_pu_polygons <- get_sim_zones_pu_polygons()
sim_zones_features <- get_sim_zones_features()
# build minimal conservation problem with raster data
p1 <-
problem(sim_pu_raster, sim_features) %>%
add_min_set_objective() %>%
add_relative_targets(0.1) %>%
add_binary_decisions() %>%
add_default_solver(verbose = FALSE)
# solve the problem
s1 <- solve(p1)
# print solution
print(s1)
# plot solution
plot(s1, main = "solution", axes = FALSE)
# calculate number of selected planning units within solution
r1 <- eval_n_summary(p1, s1)
print(r1)
# build minimal conservation problem with polygon data
p2 <-
problem(sim_pu_polygons, sim_features, cost_column = "cost") %>%
add_min_set_objective() %>%
add_relative_targets(0.1) %>%
add_binary_decisions() %>%
add_default_solver(verbose = FALSE)
# solve the problem
s2 <- solve(p2)
# plot solution
plot(s2[, "solution_1"])
# print solution
print(s2)
# calculate number of selected planning units within solution
r2 <- eval_n_summary(p2, s2[, "solution_1"])
print(r2)
# manually calculate number of selected planning units
r2_manual <- sum(s2$solution_1, na.rm = TRUE)
print(r2_manual)
# build multi-zone conservation problem with polygon data
p3 <-
problem(
sim_zones_pu_polygons, sim_zones_features,
cost_column = c("cost_1", "cost_2", "cost_3")
) %>%
add_min_set_objective() %>%
add_relative_targets(matrix(runif(15, 0.1, 0.2), nrow = 5, ncol = 3)) %>%
add_binary_decisions() %>%
add_default_solver(verbose = FALSE)
# solve the problem
s3 <- solve(p3)
# print solution
print(s3)
# create new column representing the zone id that each planning unit
# was allocated to in the solution
s3$solution <- category_vector(
s3[, c("solution_1_zone_1", "solution_1_zone_2", "solution_1_zone_3")]
)
s3$solution <- factor(s3$solution)
# plot solution
plot(s3[, "solution"])
# calculate number of selected planning units within solution
r3 <- eval_n_summary(
p3, s3[, c("solution_1_zone_1", "solution_1_zone_2", "solution_1_zone_3")]
)
print(r3)
## End(Not run)
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