The purpose of this vignette is to provide an overview of direct multi-step-ahead forecasting with multiple time series in forecastML
. The benefits to modeling multiple time series in one go with a single model or ensemble of models include (a) modeling simplicity, (b) potentially more robust results from pooling data across time series, and (c) solving the cold-start problem when few data points are available for a given time series.
To forecast with multiple/grouped/hierarchical time series in forecastML
, your data need the following characteristics:
The same outcome is being forecasted across time series.
Data are in a long format with a single outcome column–i.e., time series are stacked on top of each other in a data.frame.
There are 1 or more grouping columns.
There may be 1 or more static features that are constant through time but differ between time series–e.g., a fixed location, store square footage, species of animal etc.
The time series are regularly spaced and have no missing rows or gaps in time. Irregular or sparse time series with many NA
s can be modeled in this framework, but missing rows will result in incorrect feature lags when using create_lagged_df()
which is the first step in the forecastML
workflow. To fix any gaps in data collection, use the fill_gaps()
function. Handling the resulting missing values in the target being forecasted and any dynamic features can be done (a) prior to create_lagged_df()
or (b) in the user-defined model training function.
To illustrate forecasting with multiple time series, we’ll use the data_buoy
dataset that comes with the package. This dataset consists of daily sensor measurements of several environmental conditions collected by 14 buoys in Lake Michigan from 2012 through 2018. The data were obtained from NOAA’s National Buoy Data Center available at https://www.ndbc.noaa.gov/ using the rnoaa
package.
Outcome: Average daily wind speed in Lake Michigan.
Forecast horizon: Daily, 1 to 30 days into the future which is essentially January 2019 for this dataset.
Time series: 14 outcome time series collected from buoys throughout Lake Michigan.
Model: A single gradient boosted tree model with xgboost
for each of 3 direct forecast horizons.
data_buoy_gaps
consists of:
date
: A date column which will be removed for modeling.
buoy_id
: Group ID for unique time series.
wind_spd
: The outcome which is treated as a lagged feature by default.
lat
and lon
: Latitude and longitude which are features that are static or unchanging through time.
day
and year
: Dynamic features which won’t be lagged but whose future values will be filled in when forecasting.
air_temperature
and sea_surface_temperature
: Data collected from the buoys through time (lagged features).
forecastML::fill_gaps
The wind speed data has some gaps in it: Some buoys collected data throughout the year, others only during the summer months. These gaps in data collection would result in incorrect feature lags in create_lagged_df()
as the previous row in the dataset for a given buoy–a lag of 1–may be several months in the past.
To fix this problem, we’ll run fill_gaps()
to fill in the rows for the missing dates. The added rows will appear between min(date)
for each buoy and max(date)
across all buoys. For example, buoy 45186 that only started data collection in 2018 won’t have additional rows with NA
s for 2012 through 2017; only gaps since the start of data collection in 2018 to the most recent date will be filled in.
After running fill_gaps()
, the following columns have been filled in and have no NA
s: date
, buoy_id
, lat
, and lon
.
After running fill_gaps()
, the following columns now have additional NA
s: our wind_spd
target and the dynamic features.
Notice that the input dataset and the returned dataset have the same columns in the same order with the same data types.
data <- forecastML::fill_gaps(data_buoy_gaps, date_col = 1, frequency = '1 day',
groups = 'buoy_id', static_features = c('lat', 'lon'))
print(list(paste0("The original dataset with gaps in data collection is ", nrow(data_buoy_gaps), " rows."),
paste0("The modified dataset with no gaps in data collection from fill_gaps() is ", nrow(data), " rows.")))
## [[1]]
## [1] "The original dataset with gaps in data collection is 23646 rows."
##
## [[2]]
## [1] "The modified dataset with no gaps in data collection from fill_gaps() is 31225 rows."
day
and year
. These features are deterministic and won’t be lagged in the modeling dataset. We could also impute missing values for air_temperature
and sea_surface_temperature
, but we’ll let our xgboost
model handle these NA
s.We’ll simply and incorrectly set our grouping column, buoy_id
, to numeric to work smoothly with xgboost
. Better alternatives include feature embedding, target encoding (available in the R
package catboost
), or mixed effects Random Forests.
To be clear, buoy_id
is both (a) used to identify a specific time series for creating lagged features and (b) used as a feature in the model.
forecastML::create_lagged_df
outcome_col <- 1 # The column position of our 'wind_spd' outcome (after removing the 'date' column).
horizons <- c(1, 7, 30) # Forecast 1, 1:7, and 1:30 days into the future.
lookback <- c(1:30, 360:370) # Features from 1 to 30 days in the past and annually.
dates <- data$date # Grouped time series forecasting requires dates.
data$date <- NULL # Dates, however, don't need to be in the input data.
frequency <- "1 day" # A string that works in base::seq(..., by = "frequency").
dynamic_features <- c("day", "year") # Features that change through time but which will not be lagged.
groups <- "buoy_id" # 1 forecast for each group or buoy.
static_features <- c("lat", "lon") # Features that do not change through time.
type <- "train" # Create a model-training dataset.
data_train <- forecastML::create_lagged_df(data, type = type, outcome_col = outcome_col,
horizons = horizons, lookback = lookback,
dates = dates, frequency = frequency,
dynamic_features = dynamic_features,
groups = groups, static_features = static_features,
use_future = FALSE)
DT::datatable(head(data_train$horizon_1), options = list(scrollX = TRUE))
forecastML::create_windows
skip = 730
argument to skip 2 years between validation datasets. Custom validation windows could be defined with vectors of start and stop dates given to window_start
and window_stop
.windows <- forecastML::create_windows(data_train, window_length = 365, skip = 730,
include_partial_window = FALSE)
p <- plot(windows, data_train) + theme(legend.position = "none")
p
group_filter = "buoy_id == 1"
argument to get a closer look at 1 of our 14 time series. The user-supplied filter is passed to dplyr::filter()
internally.create_lagged_df(..., type = "train")
(e.g., my_lagged_df$horizon_h),train_model()
predict()
function.Any data transformations, hyperparameter tuning, or inner loop cross-validation procedures should take place within this function, with the limitation that it ultimately needs to return()
a model suitable for the user-defined predict()
function; a list can be returned to capture meta-data such as pre-processing pipelines or hyperparameter results.
xgboost
-specific input datasets are created within this wrapper function.# The value of outcome_col can also be set in train_model() with train_model(outcome_col = 1).
model_function <- function(data, outcome_col = 1) {
# xgboost cannot handle missing outcomes data.
data <- data[!is.na(data[, outcome_col]), ]
indices <- 1:nrow(data)
set.seed(224)
train_indices <- sample(1:nrow(data), ceiling(nrow(data) * .8), replace = FALSE)
test_indices <- indices[!(indices %in% train_indices)]
data_train <- xgboost::xgb.DMatrix(data = as.matrix(data[train_indices,
-(outcome_col), drop = FALSE]),
label = as.matrix(data[train_indices,
outcome_col, drop = FALSE]))
data_test <- xgboost::xgb.DMatrix(data = as.matrix(data[test_indices,
-(outcome_col), drop = FALSE]),
label = as.matrix(data[test_indices,
outcome_col, drop = FALSE]))
params <- list("objective" = "reg:linear")
watchlist <- list(train = data_train, test = data_test)
set.seed(224)
model <- xgboost::xgb.train(data = data_train, params = params,
max.depth = 8, nthread = 2, nrounds = 30,
metrics = "rmse", verbose = 0,
early_stopping_rounds = 5,
watchlist = watchlist)
return(model)
}
forecastML::train_model
This should take ~1 minute to train our ‘3 forecast horizons’ * ‘3 validation datasets’ = 9 models.
The user-defined modeling wrapper function could be much more elaborate, in which case many more models could potentially be trained here.
These models could be trained in parallel on any OS with the very flexible future
package by un-commenting the code below and setting use_future = TRUE
. To avoid nested parallelization, models are either trained in parallel across forecast horizons or validation windows, whichever is longer (when equal, the default is parallel across forecast horizons).
#future::plan(future::multiprocess) # Multi-core or multi-session parallel training.
model_results_cv <- forecastML::train_model(lagged_df = data_train,
windows = windows,
model_name = "xgboost",
model_function = model_function,
use_future = FALSE)
xgboost
model for any horizon or validation window. Here, we show a summary()
of the 1-step-ahead model for the first validation window which is 2012.## Length Class Mode
## handle 1 xgb.Booster.handle externalptr
## raw 309461 -none- raw
## best_iteration 1 -none- numeric
## best_ntreelimit 1 -none- numeric
## best_score 1 -none- numeric
## niter 1 -none- numeric
## evaluation_log 3 data.table list
## call 10 -none- call
## params 5 -none- list
## callbacks 2 -none- list
## feature_names 128 -none- character
## nfeatures 1 -none- numeric
First, we’ll visually evaluate our model’s performance across our validation datasets.
Then we’ll forecast with each of our 9 models to get a sense of the stability of the forecasts produced from models trained on different subsets of our historical data.
The following user-defined prediction function is needed for each model:
data.frame
of the model features from forecastML::create_lagged_df(..., type = "train")
.data.frame
of predictions with 1 or 3 columns. A 1-column data.frame will produce point forecasts, and a 3-column data.frame can be used to return point, lower, and upper forecasts (column names and order do not matter).# If 'model' is passed as a named list, the prediction model would be accessed with model$model or model["model"].
prediction_function <- function(model, data_features) {
x <- xgboost::xgb.DMatrix(data = as.matrix(data_features))
data_pred <- data.frame("y_pred" = predict(model, x),
"y_pred_lower" = predict(model, x) - 2, # Optional; in practice, forecast bounds are not hard coded.
"y_pred_upper" = predict(model, x) + 2) # Optional; in practice, forecast bounds are not hard coded.
return(data_pred)
}
data_pred_cv <- predict(model_results_cv, prediction_function = list(prediction_function), data = data_train)
group_filter
and facet
arguments to focus on specific buoys.facet = group ~ horizon
. Use different combinations of model
, horizon
, group
, along with .
(on the right hand side of ~
) in a formula with ~
to quickly explore results.
forecastML::return_error
Let’s take a quick look at our historical forecast error for buoys 1:3.
We’ll look at mean absolute error (a) for each validation window, (b) for each of the direct forecast horizons (collapsed across validation windows), and global error collapsed across validation windows and direct forecast horizons.
We have 3 datasets that support forecasting 1, 1 to 7, and 1 to 30 days into the future. We’ll view the 1-day-ahead forecasting data below.
Note that the index
and horizon
columns are removed internally when passed into the user-defined predict()
function.
type <- "forecast" # Create a forecasting dataset for our predict() function.
data_forecast <- forecastML::create_lagged_df(data, type = type, outcome_col = outcome_col,
horizons = horizons, lookback = lookback,
dates = dates, frequency = frequency,
dynamic_features = dynamic_features,
groups = groups, static_features = static_features,
use_future = FALSE)
DT::datatable(head(data_forecast$horizon_1), options = list(scrollX = TRUE))
day
and year
were not lagged in our modeling dataset. This was the right choice from a modeling perspective; however, in order to forecast ‘h’ steps ahead, we need to know their future values for each forecast horizon. At present, there’s no function in forecastML
to autofill the future values of dynamic, non-lagged features so we’ll simply do it manually below.Now we’ll forecast 1, 1:7, and 1:30 days into the future with predict(..., data = data_forecast)
.
The first time step into the future is max(dates) + 1 * frequency
. Here, this is 12-31-2018 + 1 * ‘1 day’ or 1-1-2019.
data_forecasts <- predict(model_results_cv, prediction_function = list(prediction_function), data = data_forecast)
xgboost
here–and direct forecast horizon. Because there are 3 xgboost
models for each direct forecast horizon there are 3 points/lines for each buoy within each direct forecast horizon.The modeling steps are more or less the same as in the nested cross-validation modeling described above so we’ll skip the explanations from here on out.
Notice that by this point in the modeling process, the optimal hyperparameters that gave the best performance on the outer-loop validation datasets have already been identified (see the package overview vignette). Incorporating the optimal hyperparameters in a final model would occur in a new user-defined modeling wrapper function.
Train across all data by setting window_length = 0
.
windows <- forecastML::create_windows(data_train, window_length = 0)
p <- plot(windows, data_train) + theme(legend.position = "none")
p
forecastML::combine_forecasts
The final step in the forecastML
framework is to combine multiple direct-horizon forecast models with combine_forecasts()
to produce a single h-step-ahead forecast.
The default approach, type = 'horizon'
, is to combine forecasts across models such that short-term models produce the shorter-term forecasts and long-term models produce the longer-term forecasts. This implies that, for our 30-day-ahead forecast,
data_combined <- forecastML::combine_forecasts(data_forecasts)
# Plot a background dataset of actuals using the most recent data.
data_actual <- data[dates >= as.Date("2018-11-01"), ]
actual_indices <- dates[dates >= as.Date("2018-11-01")]
# Plot all final forecasts plus historical data.
plot(data_combined, data_actual = data_actual, actual_indices = actual_indices)
facet = ~ group
. We’ll also filter to examine buoys 1, 11, and 12 because they have different historical patterns of missing data.plot(data_combined, data_actual = data_actual, actual_indices = actual_indices,
facet = group ~ ., group_filter = "buoy_id %in% c(1, 11, 12)")
# Plot final forecasts for a single buoy plus historical data.
plot(data_combined, data_actual = data_actual, actual_indices = actual_indices,
group_filter = "buoy_id == 10")