Detection prevalence
Detection prevalence is defined as the number of predicted positive events (both true positive and false positive) divided by the total number of predictions.
detection_prevalence(data, ...) ## S3 method for class 'data.frame' detection_prevalence( data, truth, estimate, estimator = NULL, na_rm = TRUE, case_weights = NULL, event_level = yardstick_event_level(), ... ) detection_prevalence_vec( truth, estimate, estimator = NULL, na_rm = TRUE, case_weights = NULL, event_level = yardstick_event_level(), ... )
data: Either a data.frame containing the columns specified by the truth and estimate arguments, or a table/matrix where the true class results should be in the columns of the table.
...: Not currently used.
truth: The column identifier for the true class results (that is a factor). This should be an unquoted column name although this argument is passed by expression and supports quasiquotation (you can unquote column names). For _vec() functions, a factor vector.
estimate: The column identifier for the predicted class results (that is also factor). As with truth this can be specified different ways but the primary method is to use an unquoted variable name. For _vec() functions, a factor vector.
estimator: One of: "binary", "macro", "macro_weighted", or "micro" to specify the type of averaging to be done. "binary" is only relevant for the two class case. The other three are general methods for calculating multiclass metrics. The default will automatically choose "binary" or "macro" based on estimate.
na_rm: A logical value indicating whether NA
values should be stripped before the computation proceeds.
case_weights: The optional column identifier for case weights. This should be an unquoted column name that evaluates to a numeric column in data. For _vec() functions, a numeric vector, hardhat::importance_weights(), or hardhat::frequency_weights().
event_level: A single string. Either "first" or "second" to specify which level of truth to consider as the "event". This argument is only applicable when estimator = "binary". The default uses an internal helper that defaults to "first".
A tibble with columns .metric, .estimator, and .estimate and 1 row of values.
For grouped data frames, the number of rows returned will be the same as the number of groups.
For detection_prevalence_vec(), a single numeric value (or NA).
There is no common convention on which factor level should automatically be considered the "event" or "positive" result when computing binary classification metrics. In yardstick, the default is to use the first level. To alter this, change the argument event_level to "second" to consider the last level of the factor the level of interest. For multiclass extensions involving one-vs-all comparisons (such as macro averaging), this option is ignored and the "one" level is always the relevant result.
Macro, micro, and macro-weighted averaging is available for this metric. The default is to select macro averaging if a truth factor with more than 2 levels is provided. Otherwise, a standard binary calculation is done. See vignette("multiclass", "yardstick") for more information.
# Two class data("two_class_example") detection_prevalence(two_class_example, truth, predicted) # Multiclass library(dplyr) data(hpc_cv) hpc_cv %>% filter(Resample == "Fold01") %>% detection_prevalence(obs, pred) # Groups are respected hpc_cv %>% group_by(Resample) %>% detection_prevalence(obs, pred) # Weighted macro averaging hpc_cv %>% group_by(Resample) %>% detection_prevalence(obs, pred, estimator = "macro_weighted") # Vector version detection_prevalence_vec( two_class_example$truth, two_class_example$predicted ) # Making Class2 the "relevant" level detection_prevalence_vec( two_class_example$truth, two_class_example$predicted, event_level = "second" )
Other class metrics: accuracy(), bal_accuracy(), f_meas(), j_index(), kap(), mcc(), npv(), ppv(), precision(), recall(), sens(), spec()
Max Kuhn
Useful links