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Iteratively forecast with nested modeling
Why is nested forecasting important? For starters, the ability to iteratively forecast time series with many models that are trained on many individual groups has been a huge request from students in our Time Series Course. Why? Because two methods exist that get results:
Global Modeling: Best for scalability using a Global Models and a Panel Data structure. See Forecasting with Global Models.
Iterative Forecasting: Best for accuracy using a Nested Data Structure. Takes longer than global model (more resources due to for-loop iteration), but can yield great results.
We’ve incorporated a new approach called “nested forecasting” to help perform Iterative Forecasting.
The core idea of nested forecasting is to convert a dataset containing many time series groups into a nested data set, then fit many models to each of the nested datasets. The result is an iterative forecasting process that generates Nested Modeltime Tables with all of the forecast attributes needed to make decisions.
Nested ensembling applies the concept of ensembling, which is generally averaging many individual models (called submodels) to produce a more stable model that sometimes improves over the best individual model.
We can apply the ensembling techniques to iterative or nested forecasting. In this tutorial, we will show you how to perform:
Average Ensembles using ensemble_nested_average()
.
These are the simplest models.
Weighted Ensembles using ensemble_nested_weighted()
.
These allow the user to provide “loadings” to distribute the weighting
to the top models, which can sometimes improve over the simple average
ensembles.
Let’s go!
We’ll showcase nested ensembling for iterative forecasting in this short tutorial.
Load the following libraries.
library(tidymodels)
library(modeltime)
library(modeltime.ensemble)
library(dplyr)
library(timetk)
library(gt)
nested-ensembles.R
Read in the Walmart Sales Weekly data (comes with
timetk
).
data_tbl <- walmart_sales_weekly %>%
select(id, date = Date, value = Weekly_Sales) %>%
filter(id %in% c("1_1", "1_3"))
data_tbl
#> # A tibble: 286 × 3
#> id date value
#> <fct> <date> <dbl>
#> 1 1_1 2010-02-05 24924.
#> 2 1_1 2010-02-12 46039.
#> 3 1_1 2010-02-19 41596.
#> 4 1_1 2010-02-26 19404.
#> 5 1_1 2010-03-05 21828.
#> 6 1_1 2010-03-12 21043.
#> 7 1_1 2010-03-19 22137.
#> 8 1_1 2010-03-26 26229.
#> 9 1_1 2010-04-02 57258.
#> 10 1_1 2010-04-09 42961.
#> # ℹ 276 more rows
nested-ensembles.R
We can get a quick visual of the two time series we will forecast.
nested-ensembles.R
The most critical stage in “Nested Forecasting” is data preparation, making sure that the input to the nested forecasting workflow is in the appropriate structure. We’ve included several functions to help that involve a bit of forethought that can be broken into 3 steps:
Extending each of the times series: How far into
the future do you need to predict for each time series? See
extend_timeseries()
.
Nesting by the grouping variable: This is where
you create the nested structure. You’ll identify the ID column that
separates each time series, and the number of timestamps to include in
the “.future_data” and optionally “.actual_data”. Typically, you’ll
select the same .length_future
as your extension from the
previous step. See nest_timeseries()
.
Train/Test Set Splitting: Finally, you’ll take
your .actual_data
and convert into train/test splits that
can be used for accuracy and confidence interval estimation. See
split_nested_timeseries()
.
Here are the 3-steps in action:
nested_data_tbl <- data_tbl %>%
# Step 1: Extend
extend_timeseries(
.id_var = id,
.date_var = date,
.length_future = 52
) %>%
# Step 2: Nest
nest_timeseries(
.id_var = id,
.length_future = 52,
.length_actual = 52*2
) %>%
# Step 3: Split Train/Test
split_nested_timeseries(
.length_test = 52
)
nested_data_tbl
#> # A tibble: 2 × 4
#> id .actual_data .future_data .splits
#> <fct> <list> <list> <list>
#> 1 1_1 <tibble [104 × 2]> <tibble [52 × 2]> <split [52|52]>
#> 2 1_3 <tibble [104 × 2]> <tibble [52 × 2]> <split [52|52]>
nested-ensembles.R
Next, we move into the Nested Modeltime Workflow now that nested data has been created. The Nested Modeltime Workflow includes 3 steps:
Modeling Fitting: This is the training stage where we fit to training data. The test forecast is generated from this step.
Create tidymodels workflows.
modeltime_nested_fit()
: Used to fit the submodels to
the training data.
ensemble_nested_average()
or
ensemble_nested_weighted()
: Used to make ensembles from the
submodels.
Model Evaluation and Selection: This is where we
review model performance and select the best model by minimizing or
maximizing an error metric. See
modeltime_nested_select_best()
.
Model Refitting: This is the final fitting stage
where we fit to actual data. The future forecast is
generated from this step. See
modeltime_nested_refit()
.
First, we create tidymodels
workflows for the various
models that you intend to create.
A common modeling method is prophet, that can be created using
prophet_reg()
. We’ll create a workflow. Note that we use
the extract_nested_train_split(nested_data_tbl)
to help us
build preprocessing features.
rec_prophet <- recipe(value ~ date, extract_nested_train_split(nested_data_tbl))
wflw_prophet <- workflow() %>%
add_model(
prophet_reg("regression", seasonality_yearly = TRUE) %>%
set_engine("prophet")
) %>%
add_recipe(rec_prophet)
nested-ensembles.R
Next, we can use a machine learning method that can get good results:
XGBoost. We will add a few extra features in the recipe feature
engineering step to generate features that tend to get better modeling
results. Note that we use the
extract_nested_train_split(nested_data_tbl)
to help us
build preprocessing features.
rec_xgb <- recipe(value ~ ., extract_nested_train_split(nested_data_tbl)) %>%
step_timeseries_signature(date) %>%
step_rm(date) %>%
step_zv(all_predictors()) %>%
step_dummy(all_nominal_predictors(), one_hot = TRUE)
wflw_xgb <- workflow() %>%
add_model(boost_tree("regression") %>% set_engine("xgboost")) %>%
add_recipe(rec_xgb)
nested-ensembles.R
With a couple of modeling workflows in hand, we are now ready to test
them on each of the time series. We start by using the
modeltime_nested_fit()
function, which iteratively fits
each model to each of the nested time series train/test “.splits”
column.
nested_modeltime_tbl <- modeltime_nested_fit(
# Nested data
nested_data = nested_data_tbl,
# Add workflows
wflw_prophet,
wflw_xgb
)
#> Fitting models on training data... ■■■■■■■■■■■■■■■■ 50% | ETA:…
#> Fitting models on training data... ■■■■■■■■■■■■■■■■■■■■■■■■■■■■■■■ 100% | ETA:…
#> # Nested Modeltime Table
#>
#> Trained on: .splits | Forecast Errors: [0] | Conf Method: conformal_default |
#> Conf Interval: 0.95
#> # A tibble: 2 × 5
#> id .actual_data .future_data .splits .modeltime_tables
#> <fct> <list> <list> <list> <list>
#> 1 1_1 <tibble [104 × 2]> <tibble [52 × 2]> <split [52|52]> <mdl_tm_t [2 × 5]>
#> 2 1_3 <tibble [104 × 2]> <tibble [52 × 2]> <split [52|52]> <mdl_tm_t [2 × 5]>
nested-ensembles.R
This adds a new column with .modeltime_tables
for each
of the data sets and has created several logged
attributes that are part of the “Nested Modeltime Table”. We
also can see that the models were trained on “.splits” and none of the
models had any errors.
This is kind of advanced, but because our accuracy functions
(table_modeltime_accuracy(.interactive = FALSE)
) produce
static gt
table, we can make a function to highlight rows
by group.
tab_style_by_group <- function(object, ..., style) {
subset_log <- object[["_boxhead"]][["type"]]=="row_group"
grp_col <- object[["_boxhead"]][["var"]][subset_log] %>% rlang::sym()
object %>%
tab_style(
style = style,
locations = cells_body(
rows = .[["_data"]] %>%
tibble::rowid_to_column("rowid") %>%
group_by(!!grp_col) %>%
filter(...) %>%
ungroup() %>%
pull(rowid)
)
)
}
nested-ensembles.R
And now we can see which models are the winners, performing the best by group with the lowest RMSE (root mean squared error).
nested_modeltime_tbl %>%
extract_nested_test_accuracy() %>%
group_by(id) %>%
table_modeltime_accuracy(.interactive = FALSE) %>%
tab_style_by_group(
rmse == min(rmse),
style = cell_fill(color = "lightblue")
)
Accuracy Table | ||||||||
.model_id | .model_desc | .type | mae | mape | mase | smape | rmse | rsq |
---|---|---|---|---|---|---|---|---|
1_1 | ||||||||
1 | PROPHET | Test | 10071.47 | 45.88 | 1.99 | 59.97 | 11776.87 | 0.38 |
2 | XGBOOST | Test | 6236.79 | 25.31 | 1.23 | 24.57 | 9017.22 | 0.19 |
1_3 | ||||||||
1 | PROPHET | Test | 3539.80 | 29.87 | 1.37 | 25.46 | 4707.77 | 0.80 |
2 | XGBOOST | Test | 3085.78 | 18.81 | 1.20 | 20.40 | 5085.81 | 0.79 |
nested-ensembles.R
Now that we’ve fitted submodels, our goal is to improve on the submodels by leveraging ensembles.
We’ll give a go at an average ensemble using a
simple mean with the ensemble_nested_average()
function. We
select type = "mean"
for simple average (another option is
median ensemble, which is better when you have models with large
spikes).
nested_ensemble_1_tbl <- nested_modeltime_tbl %>%
ensemble_nested_average(
type = "mean",
keep_submodels = TRUE
)
nested_ensemble_1_tbl
#> # Nested Modeltime Table
#> # A tibble: 2 × 5
#> id .actual_data .future_data .splits .modeltime_tables
#> <fct> <list> <list> <list> <list>
#> 1 1_1 <tibble [104 × 2]> <tibble [52 × 2]> <split [52|52]> <mdl_tm_t [3 × 5]>
#> 2 1_3 <tibble [104 × 2]> <tibble [52 × 2]> <split [52|52]> <mdl_tm_t [3 × 5]>
nested-ensembles.R
We can check the accuracy again. This time the Ensemble (MEAN) outperforms both the prophet and xgboost submodels.
nested_ensemble_1_tbl %>%
extract_nested_test_accuracy() %>%
group_by(id) %>%
table_modeltime_accuracy(.interactive = FALSE) %>%
tab_style_by_group(
rmse == min(rmse),
style = cell_fill(color = "lightblue")
)
Accuracy Table | ||||||||
.model_id | .model_desc | .type | mae | mape | mase | smape | rmse | rsq |
---|---|---|---|---|---|---|---|---|
1_1 | ||||||||
1 | PROPHET | Test | 10071.47 | 45.88 | 1.99 | 59.97 | 11776.87 | 0.38 |
2 | XGBOOST | Test | 6236.79 | 25.31 | 1.23 | 24.57 | 9017.22 | 0.19 |
3 | ENSEMBLE (MEAN): 2 MODELS | Test | 5419.21 | 20.22 | 1.07 | 22.23 | 8654.52 | 0.42 |
1_3 | ||||||||
1 | PROPHET | Test | 3539.80 | 29.87 | 1.37 | 25.46 | 4707.77 | 0.80 |
2 | XGBOOST | Test | 3085.78 | 18.81 | 1.20 | 20.40 | 5085.81 | 0.79 |
3 | ENSEMBLE (MEAN): 2 MODELS | Test | 2661.82 | 18.97 | 1.03 | 17.75 | 4038.38 | 0.82 |
nested-ensembles.R
Next, we can give a go at a weighted ensemble with the
ensemble_nested_weighted()
function. A few key points about
the arguments:
loadings
: This parameter allows us to weight models
differently. Providing c(2,1)
places a 2-to-1 weighting on
the two submodels.
metric
: This parameter is determined by the
accuracy table. The default is to use the “rmse”
column. The loadings are then applied to the best (lowest) “rmse” first.
The best model will have 2/3 (66% weight) loading and the second best
will have 1/3 (33% weight).
model_ids
: This is a filtering mechanism to help us
isolate which model ID’s that we want to include as submodels. We want
to exclude Model ID 3, because this is our Ensemble Average (MEAN)
model.
control
: This uses control_nested_fit()
to control aspects of the fitting process like running in Parallel vs
Sequential and outputting verbose to provide additional information
during the fitting process.
nested_ensemble_2_tbl <- nested_ensemble_1_tbl %>%
ensemble_nested_weighted(
loadings = c(2,1),
metric = "rmse",
model_ids = c(1,2),
control = control_nested_fit(allow_par = FALSE, verbose = TRUE)
)
#> ℹ [1/2] Starting Modeltime Table: ID 1_1...
#> ✔ Model 4 Passed ENSEMBLE WEIGHTED.
#> ✔ [1/2] Finished Modeltime Table: ID 1_1
#> ℹ [2/2] Starting Modeltime Table: ID 1_3...
#> ✔ Model 4 Passed ENSEMBLE WEIGHTED.
#> ✔ [2/2] Finished Modeltime Table: ID 1_3
#> Finished in: 1.628696 secs.
#> # Nested Modeltime Table
#>
#> Trained on: .splits | Forecast Errors: [0] | Conf Method: conformal_default |
#> Conf Interval: 0.95
#> # A tibble: 2 × 5
#> id .actual_data .future_data .splits .modeltime_tables
#> <fct> <list> <list> <list> <list>
#> 1 1_1 <tibble [104 × 2]> <tibble [52 × 2]> <split [52|52]> <mdl_tm_t [4 × 5]>
#> 2 1_3 <tibble [104 × 2]> <tibble [52 × 2]> <split [52|52]> <mdl_tm_t [4 × 5]>
nested-ensembles.R
Next, let’s check the accuracy on the new ensemble. The Weighted Ensemble has improved the 1_1 time series, but not the 1_3 time series.
nested_ensemble_2_tbl %>%
extract_nested_test_accuracy() %>%
group_by(id) %>%
table_modeltime_accuracy(.interactive = FALSE) %>%
tab_style_by_group(
rmse == min(rmse),
style = cell_fill(color = "lightblue")
)
Accuracy Table | ||||||||
.model_id | .model_desc | .type | mae | mape | mase | smape | rmse | rsq |
---|---|---|---|---|---|---|---|---|
1_1 | ||||||||
1 | PROPHET | Test | 10071.47 | 45.88 | 1.99 | 59.97 | 11776.87 | 0.38 |
2 | XGBOOST | Test | 6236.79 | 25.31 | 1.23 | 24.57 | 9017.22 | 0.19 |
3 | ENSEMBLE (MEAN): 2 MODELS | Test | 5419.21 | 20.22 | 1.07 | 22.23 | 8654.52 | 0.42 |
4 | ENSEMBLE (WEIGHTED): 2 MODELS | Test | 4414.19 | 14.75 | 0.87 | 15.99 | 8320.87 | 0.41 |
1_3 | ||||||||
1 | PROPHET | Test | 3539.80 | 29.87 | 1.37 | 25.46 | 4707.77 | 0.80 |
2 | XGBOOST | Test | 3085.78 | 18.81 | 1.20 | 20.40 | 5085.81 | 0.79 |
3 | ENSEMBLE (MEAN): 2 MODELS | Test | 2661.82 | 18.97 | 1.03 | 17.75 | 4038.38 | 0.82 |
4 | ENSEMBLE (WEIGHTED): 2 MODELS | Test | 2771.82 | 21.25 | 1.08 | 19.12 | 4067.88 | 0.82 |
nested-ensembles.R
Using the accuracy data, we can pick a metric and select the best
model based on that metric. The available metrics are in the
default_forecast_accuracy_metric_set()
. Make sure to select
minimize
based on the metric. The
filter_test_forecasts
parameter tells the function to
filter the logged test forecasts to just the best.
best_nested_modeltime_tbl <- nested_ensemble_2_tbl %>%
modeltime_nested_select_best(
metric = "rmse",
minimize = TRUE,
filter_test_forecasts = TRUE
)
nested-ensembles.R
The best model selections can be accessed with
extract_nested_best_model_report()
.
best_nested_modeltime_tbl %>%
extract_nested_best_model_report() %>%
table_modeltime_accuracy(.interactive = FALSE)
Accuracy Table | |||||||||
id | .model_id | .model_desc | .type | mae | mape | mase | smape | rmse | rsq |
---|---|---|---|---|---|---|---|---|---|
1_1 | 4 | ENSEMBLE (WEIGHTED): 2 MODELS | Test | 4414.19 | 14.75 | 0.87 | 15.99 | 8320.87 | 0.41 |
1_3 | 3 | ENSEMBLE (MEAN): 2 MODELS | Test | 2661.82 | 18.97 | 1.03 | 17.75 | 4038.38 | 0.82 |
nested-ensembles.R
Once we’ve selected the best models, we can easily visualize the best forecasts by time series. Note that the nested test forecast logs have been modified to isolate the best models.
best_nested_modeltime_tbl %>%
extract_nested_test_forecast() %>%
group_by(id) %>%
plot_modeltime_forecast(
.facet_ncol = 1,
.interactive = FALSE
)
nested-ensembles.R
With the best models in hand, we can make our future forecasts by refitting the models to the full dataset.
If the best models have been selected, the only the best models will be refit.
If best models have not been selected, then all models will be refit.
We’ve selected our best models, and will move forward with refitting
and future forecast logging using the
modeltime_nested_refit()
function.
nested_modeltime_refit_tbl <- best_nested_modeltime_tbl %>%
modeltime_nested_refit(
control = control_nested_refit(verbose = TRUE)
)
#> ℹ [1/2] Starting Modeltime Table: ID 1_1...
#> ✔ Model 4 Passed ENSEMBLE (WEIGHTED): 2 MODELS.
#> ✔ [1/2] Finished Modeltime Table: ID 1_1
#> ℹ [2/2] Starting Modeltime Table: ID 1_3...
#> ✔ Model 3 Passed ENSEMBLE (MEAN): 2 MODELS.
#> ✔ [2/2] Finished Modeltime Table: ID 1_3
#> Finished in: 1.089689 secs.
nested-ensembles.R
We can see that the nested modeltime table appears the same, but has
now been trained on .actual_data
.
#> # Nested Modeltime Table
#>
#> Trained on: .actual_data | Forecast Errors: [0] | Conf Method:
#> conformal_default | Conf Interval: 0.95
#> # A tibble: 2 × 5
#> id .actual_data .future_data .splits .modeltime_tables
#> <fct> <list> <list> <list> <list>
#> 1 1_1 <tibble [104 × 2]> <tibble [52 × 2]> <split [52|52]> <mdl_tm_t [1 × 5]>
#> 2 1_3 <tibble [104 × 2]> <tibble [52 × 2]> <split [52|52]> <mdl_tm_t [1 × 5]>
nested-ensembles.R
Nested ensembling is a powerful technique that can improve forecasting accuracy. But, this is just a small portion of what can be done to take your forecasting to the next level… If you want to become a forecasting expert for your organization, then take the read on!
Become the forecasting expert for your organization
High-Performance Time Series Course
Time series is changing. Businesses now need 10,000+ time series forecasts every day. This is what I call a High-Performance Time Series Forecasting System (HPTSF) - Accurate, Robust, and Scalable Forecasting.
High-Performance Forecasting Systems will save companies by improving accuracy and scalability. Imagine what will happen to your career if you can provide your organization a “High-Performance Time Series Forecasting System” (HPTSF System).
I teach how to build a HPTFS System in my High-Performance Time Series Forecasting Course. You will learn:
Modeltime
- 30+ Models (Prophet, ARIMA, XGBoost, Random
Forest, & many more)GluonTS
(Competition Winners)
Become the Time Series Expert for your organization.
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.