Title: | Evaluate Trending Models |
---|---|
Description: | Provides a coherent interface for evaluating models fit with the trending package. This package is part of the RECON (<https://www.repidemicsconsortium.org/>) toolkit for outbreak analysis. |
Authors: | Dirk Schumacher [aut], Thibaut Jombart [aut, cre], Tim Taylor [ctb] |
Maintainer: | Thibaut Jombart <[email protected]> |
License: | MIT + file LICENSE |
Version: | 0.0.1.9001 |
Built: | 2024-11-09 04:38:32 UTC |
Source: | https://github.com/reconverse/trendeval |
Generic calculate_aic()
returns the Akaike's 'An Information Criterion' for
the given input.
calculate_aic(x, ...) ## Default S3 method: calculate_aic(x, ...) ## S3 method for class 'trending_model' calculate_aic(x, data, as_tibble = FALSE, ...) ## S3 method for class 'list' calculate_aic(x, data, ...) ## S3 method for class 'trending_fit' calculate_aic(x, as_tibble = FALSE, ...) ## S3 method for class 'trending_fit_tbl' calculate_aic(x, ...)
calculate_aic(x, ...) ## Default S3 method: calculate_aic(x, ...) ## S3 method for class 'trending_model' calculate_aic(x, data, as_tibble = FALSE, ...) ## S3 method for class 'list' calculate_aic(x, data, ...) ## S3 method for class 'trending_fit' calculate_aic(x, as_tibble = FALSE, ...) ## S3 method for class 'trending_fit_tbl' calculate_aic(x, ...)
x |
An R object. |
... |
Not currently used. |
data |
a |
as_tibble |
Should the result be returned as tibble
( |
Specific methods are given for
trending_fit
and
trending_fit_tbl
objects. The default
method applies stats::AIC()
directly.
For a single trending_fit
input, if
as_tibble = FALSE
the object returned will be a list with entries:
metric: "AIC"
result: the resulting AIC value fit (NULL if the calculation failed)
warnings: any warnings generated during calculation
errors: any errors generated during calculation
If as_tibble = TRUE
, or the input is a
trending_fit_tbl
, then the output
will be a tibble with one row for each fitted model
columns corresponding to output generated with single model input.
Tim Taylor
#' @examples x = rnorm(100, mean = 0) y = rpois(n = 100, lambda = exp(1.5 + 0.5*x)) dat <- data.frame(x = x, y = y) poisson_model <- glm_model(y ~ x , family = "poisson") negbin_model <- glm_nb_model(y ~ x) fitted_model <- fit(poisson_model, dat) fitted_models <- fit(list(poisson_model, negbin_model), data = dat)
calculate_aic(poisson_model, dat) calculate_aic(fitted_model) calculate_aic(fitted_model, as_tibble = TRUE) calculate_aic(fitted_models)
Generic calculate_mae()
returns the root mean square error for the given
input.
calculate_mae(x, ...) ## Default S3 method: calculate_mae(x, ...) ## S3 method for class 'trending_model' calculate_mae(x, data, na.rm = TRUE, as_tibble = TRUE, ...) ## S3 method for class 'list' calculate_mae(x, data, na.rm = TRUE, ...) ## S3 method for class 'trending_fit' calculate_mae(x, new_data, na.rm = TRUE, as_tibble = TRUE, ...) ## S3 method for class 'trending_fit_tbl' calculate_mae(x, new_data, na.rm = TRUE, ...) ## S3 method for class 'trending_predict' calculate_mae(x, na.rm = TRUE, as_tibble = TRUE, ...) ## S3 method for class 'trending_predict_tbl' calculate_mae(x, na.rm = TRUE, ...) ## S3 method for class 'trending_prediction' calculate_mae(x, na.rm = TRUE, as_tibble = TRUE, ...)
calculate_mae(x, ...) ## Default S3 method: calculate_mae(x, ...) ## S3 method for class 'trending_model' calculate_mae(x, data, na.rm = TRUE, as_tibble = TRUE, ...) ## S3 method for class 'list' calculate_mae(x, data, na.rm = TRUE, ...) ## S3 method for class 'trending_fit' calculate_mae(x, new_data, na.rm = TRUE, as_tibble = TRUE, ...) ## S3 method for class 'trending_fit_tbl' calculate_mae(x, new_data, na.rm = TRUE, ...) ## S3 method for class 'trending_predict' calculate_mae(x, na.rm = TRUE, as_tibble = TRUE, ...) ## S3 method for class 'trending_predict_tbl' calculate_mae(x, na.rm = TRUE, ...) ## S3 method for class 'trending_prediction' calculate_mae(x, na.rm = TRUE, as_tibble = TRUE, ...)
x |
An R object. |
... |
Not currently used. |
data |
a |
na.rm |
Should NA values should be removed before calculation of metric (passed to the underlying function yardstick::mae_vec). |
as_tibble |
Should the result be returned as tibble
( |
new_data |
a |
Specific methods are given for trending_model
(and lists of
these), trending_fit
,
trending_fit_tbl
,
trending_predict_tbl
,
trending_predict_tbl
and
trending_prediction
objects. Each of these are simply wrappers around the
yardstick::mae_vec with the addition of explicit error handling.
For a single trending_fit
input, if
as_tibble = FALSE
the object returned will be a list with entries:
metric: "mae"
result: the resulting mae value (NULL if the calculation failed)
warnings: any warnings generated during calculation
errors: any errors generated during calculation
If as_tibble = TRUE
, or for the other trending
classes, then the output
will be a tibble with one row for each fitted model
columns corresponding to output generated with single model input.
Tim Taylor
#' @examples x = rnorm(100, mean = 0) y = rpois(n = 100, lambda = exp(1.5 + 0.5*x)) dat <- data.frame(x = x, y = y) poisson_model <- glm_model(y ~ x , family = "poisson") negbin_model <- glm_nb_model(y ~ x) fitted_model <- fit(poisson_model, dat) fitted_models <- fit(list(poisson_model, negbin_model), data = dat)
calculate_mae(poisson_model, dat) calculate_mae(fitted_model) calculate_mae(fitted_model, as_tibble = TRUE) calculate_mae(fitted_models)
Generic calculate_rmse()
returns the root mean square error for the given
input.
calculate_rmse(x, ...) ## Default S3 method: calculate_rmse(x, ...) ## S3 method for class 'trending_model' calculate_rmse(x, data, na.rm = TRUE, as_tibble = TRUE, ...) ## S3 method for class 'list' calculate_rmse(x, data, na.rm = TRUE, ...) ## S3 method for class 'trending_fit' calculate_rmse(x, new_data, na.rm = TRUE, as_tibble = TRUE, ...) ## S3 method for class 'trending_fit_tbl' calculate_rmse(x, new_data, na.rm = TRUE, ...) ## S3 method for class 'trending_predict' calculate_rmse(x, na.rm = TRUE, as_tibble = TRUE, ...) ## S3 method for class 'trending_predict_tbl' calculate_rmse(x, na.rm = TRUE, ...) ## S3 method for class 'trending_prediction' calculate_rmse(x, na.rm = TRUE, as_tibble = TRUE, ...)
calculate_rmse(x, ...) ## Default S3 method: calculate_rmse(x, ...) ## S3 method for class 'trending_model' calculate_rmse(x, data, na.rm = TRUE, as_tibble = TRUE, ...) ## S3 method for class 'list' calculate_rmse(x, data, na.rm = TRUE, ...) ## S3 method for class 'trending_fit' calculate_rmse(x, new_data, na.rm = TRUE, as_tibble = TRUE, ...) ## S3 method for class 'trending_fit_tbl' calculate_rmse(x, new_data, na.rm = TRUE, ...) ## S3 method for class 'trending_predict' calculate_rmse(x, na.rm = TRUE, as_tibble = TRUE, ...) ## S3 method for class 'trending_predict_tbl' calculate_rmse(x, na.rm = TRUE, ...) ## S3 method for class 'trending_prediction' calculate_rmse(x, na.rm = TRUE, as_tibble = TRUE, ...)
x |
An R object. |
... |
Not currently used. |
data |
a |
na.rm |
Should NA values should be removed before calculation of metric (passed to the underlying function yardstick::rmse_vec). |
as_tibble |
Should the result be returned as tibble
( |
new_data |
a |
Specific methods are given for trending_model
(and lists of
these), trending_fit
,
trending_fit_tbl
,
trending_predict_tbl
,
trending_predict_tbl
and
trending_prediction
objects. Each of these are simply wrappers around the
yardstick::rmse_vec with the addition of explicit error handling.
For a single trending_fit
input, if
as_tibble = FALSE
the object returned will be a list with entries:
metric: "rmse"
result: the resulting rmse value (NULL if the calculation failed)
warnings: any warnings generated during calculation
errors: any errors generated during calculation
If as_tibble = TRUE
, or for the other trending
classes, then the output
will be a tibble with one row for each fitted model
columns corresponding to output generated with single model input.
Tim Taylor
#' @examples x = rnorm(100, mean = 0) y = rpois(n = 100, lambda = exp(1.5 + 0.5*x)) dat <- data.frame(x = x, y = y) poisson_model <- glm_model(y ~ x , family = "poisson") negbin_model <- glm_nb_model(y ~ x) fitted_model <- fit(poisson_model, dat) fitted_models <- fit(list(poisson_model, negbin_model), data = dat)
calculate_rmse(poisson_model, dat) calculate_rmse(fitted_model) calculate_rmse(fitted_model, as_tibble = TRUE) calculate_rmse(fitted_models)
Generic calculate_rsq()
returns the root mean square error for the given
input.
calculate_rsq(x, ...) ## Default S3 method: calculate_rsq(x, ...) ## S3 method for class 'trending_model' calculate_rsq(x, data, na.rm = TRUE, as_tibble = TRUE, ...) ## S3 method for class 'list' calculate_rsq(x, data, na.rm = TRUE, ...) ## S3 method for class 'trending_fit' calculate_rsq(x, new_data, na.rm = TRUE, as_tibble = TRUE, ...) ## S3 method for class 'trending_fit_tbl' calculate_rsq(x, new_data, na.rm = TRUE, ...) ## S3 method for class 'trending_predict' calculate_rsq(x, na.rm = TRUE, as_tibble = TRUE, ...) ## S3 method for class 'trending_predict_tbl' calculate_rsq(x, na.rm = TRUE, ...) ## S3 method for class 'trending_prediction' calculate_rsq(x, na.rm = TRUE, as_tibble = TRUE, ...)
calculate_rsq(x, ...) ## Default S3 method: calculate_rsq(x, ...) ## S3 method for class 'trending_model' calculate_rsq(x, data, na.rm = TRUE, as_tibble = TRUE, ...) ## S3 method for class 'list' calculate_rsq(x, data, na.rm = TRUE, ...) ## S3 method for class 'trending_fit' calculate_rsq(x, new_data, na.rm = TRUE, as_tibble = TRUE, ...) ## S3 method for class 'trending_fit_tbl' calculate_rsq(x, new_data, na.rm = TRUE, ...) ## S3 method for class 'trending_predict' calculate_rsq(x, na.rm = TRUE, as_tibble = TRUE, ...) ## S3 method for class 'trending_predict_tbl' calculate_rsq(x, na.rm = TRUE, ...) ## S3 method for class 'trending_prediction' calculate_rsq(x, na.rm = TRUE, as_tibble = TRUE, ...)
x |
An R object. |
... |
Not currently used. |
data |
a |
na.rm |
Should NA values should be removed before calculation of metric (passed to the underlying function yardstick::rsq_vec). |
as_tibble |
Should the result be returned as tibble
( |
new_data |
a |
Specific methods are given for trending_model
(and lists of
these), trending_fit
,
trending_fit_tbl
,
trending_predict_tbl
,
trending_predict_tbl
and
trending_prediction
objects. Each of these are simply wrappers around the
yardstick::rsq_vec with the addition of explicit error handling.
For a single trending_fit
input, if
as_tibble = FALSE
the object returned will be a list with entries:
metric: "rsq"
result: the resulting rsq value (NULL if the calculation failed)
warnings: any warnings generated during calculation
errors: any errors generated during calculation
If as_tibble = TRUE
, or for the other trending
classes, then the output
will be a tibble with one row for each fitted model
columns corresponding to output generated with single model input.
Tim Taylor
#' @examples x = rnorm(100, mean = 0) y = rpois(n = 100, lambda = exp(1.5 + 0.5*x)) dat <- data.frame(x = x, y = y) poisson_model <- glm_model(y ~ x , family = "poisson") negbin_model <- glm_nb_model(y ~ x) fitted_model <- fit(poisson_model, dat) fitted_models <- fit(list(poisson_model, negbin_model), data = dat)
calculate_rsq(poisson_model, dat) calculate_rsq(fitted_model) calculate_rsq(fitted_model, as_tibble = TRUE) calculate_rsq(fitted_models)
evaluate_aic()
is a a generic for evaluating the Akaike's
'An Information Criterion' for a given input
evaluate_aic(x, ...) ## Default S3 method: evaluate_aic(x, ...) ## S3 method for class 'trending_model' evaluate_aic(x, data, as_tibble = FALSE, ...) ## S3 method for class 'list' evaluate_aic(x, data, ...)
evaluate_aic(x, ...) ## Default S3 method: evaluate_aic(x, ...) ## S3 method for class 'trending_model' evaluate_aic(x, data, as_tibble = FALSE, ...) ## S3 method for class 'list' evaluate_aic(x, data, ...)
x |
An R object. |
... |
Not currently used. |
data |
a |
as_tibble |
Should the result be returned as tibble
( |
Specific methods are given for
trending_fit
and lists of these
models.
If as_tibble = TRUE
, or the input is a list of models then the
output will be a tibble with one row for each fitted
model columns corresponding to output generated with single model input.
Tim Taylor
#' @examples x = rnorm(100, mean = 0) y = rpois(n = 100, lambda = exp(1.5 + 0.5*x)) dat <- data.frame(x = x, y = y) poisson_model <- glm_model(y ~ x , family = "poisson") negbin_model <- glm_nb_model(y ~ x)
evaluate_aic(poisson_model, dat) evaluate_aic(list(poisson_model, negbin_model), data = dat)
evaluate_resampling()
uses repeated K-fold cross-validation and
the Root Mean Square Error (RMSE) of testing sets to measure the predictive
power of a single model. Methods are provided for
trending::trending_model
(and lists of these) objects.
evaluate_resampling(x, ...) ## Default S3 method: evaluate_resampling(x, ...) ## S3 method for class 'trending_model' evaluate_resampling( x, data, metric = c("rmse", "rsq", "mae"), metric_arguments = list(na.rm = TRUE), v = nrow(data), repeats = 1, ... ) ## S3 method for class 'list' evaluate_resampling( x, data, metric = c("rmse", "rsq", "mae"), metric_arguments = list(na.rm = TRUE), v = nrow(data), repeats = 1, ... )
evaluate_resampling(x, ...) ## Default S3 method: evaluate_resampling(x, ...) ## S3 method for class 'trending_model' evaluate_resampling( x, data, metric = c("rmse", "rsq", "mae"), metric_arguments = list(na.rm = TRUE), v = nrow(data), repeats = 1, ... ) ## S3 method for class 'list' evaluate_resampling( x, data, metric = c("rmse", "rsq", "mae"), metric_arguments = list(na.rm = TRUE), v = nrow(data), repeats = 1, ... )
x |
An R object. |
... |
Not currently used. |
data |
a |
metric |
One of "rmse" (see calculate_rmse), "mae" (see calculate_mae) and "rsq" (see calculate_rsq). |
metric_arguments |
A named list of arguments passed to the underlying functions that calculate the metrics. |
v |
the number of equally sized data partitions to be used for K-fold
cross-validation; |
repeats |
the number of times the random K-fold cross validation should be repeated for; defaults to 1; larger values are likely to yield more reliable / stable results, at the expense of computational time |
These functions wrap around existing functions from several
packages. evaluate_resampling.trending_model()
and
evaluate_resampling.list()
both use rsample::vfold_cv()
for sampling
and, for the calculating the different metrics, the
yardstick package.
calculate_aic()
, calculate_rmse()
, calculate_mae()
and
calculate_rsq()
.
x <- rnorm(100, mean = 0) y <- rpois(n = 100, lambda = exp(x + 1)) dat <- data.frame(x = x, y = y) model <- trending::glm_model(y ~ x, poisson) models <- list( poisson_model = trending::glm_model(y ~ x, poisson), linear_model = trending::lm_model(y ~ x) ) evaluate_resampling(model, dat) evaluate_resampling(models, dat)
x <- rnorm(100, mean = 0) y <- rpois(n = 100, lambda = exp(x + 1)) dat <- data.frame(x = x, y = y) model <- trending::glm_model(y ~ x, poisson) models <- list( poisson_model = trending::glm_model(y ~ x, poisson), linear_model = trending::lm_model(y ~ x) ) evaluate_resampling(model, dat) evaluate_resampling(models, dat)