- 5/31/2020
forecast
method is AVAILABLE now inNARX
models!!! (DirectAutoRegressor
is not suitable to do forecast, so there is no forecast method for it.) Here is a quick start example. Check "examples/Basic usage of NARX and DirectAutoregressor.ipynb" for more details. What is the difference betweenpredict
andforecast
?
import numpy as np
from sklearn.linear_model import LinearRegression
from fireTS.models import NARX
x = np.random.randn(100, 1)
y = np.random.randn(100)
mdl = NARX(LinearRegression(), auto_order=2, exog_order=[2])
mdl.fit(x, y)
y_forecast = mdl.forecast(x, y, step=10, X_future=np.random.randn(9, 1))
fireTS
is a sklean style package for multi-variate time-series prediction. Here is a simple code snippet to showcase the awesome features provided by fireTS
package.
from fireTS.models import NARX, DirectAutoRegressor
from sklearn.ensemble import RandomForestRegressor
from xgboost import XGBRegressor
import numpy as np
# Random training data
x = np.random.randn(100, 2)
y = np.random.randn(100)
# Build a non-linear autoregression model with exogenous inputs
# using Random Forest regression as the base model
mdl1 = NARX(
RandomForestRegressor(n_estimators=10),
auto_order=2,
exog_order=[2, 2],
exog_delay=[1, 1])
mdl1.fit(x, y)
ypred1 = mdl1.predict(x, y, step=3)
# Build a general autoregression model and make multi-step prediction directly
# using XGBRegressor as the base model
mdl2 = DirectAutoRegressor(
XGBRegressor(n_estimators=10),
auto_order=2,
exog_order=[2, 2],
exog_delay=[1, 1],
pred_step=3)
mdl2.fit(x, y)
ypred2 = mdl2.predict(x, y)
sklearn
style API. The package providesfit
andpredict
methods, which is very similar tosklearn
package.- Plug-and-go. You are able to plug in any machine learning regression algorithms provided in
sklearn
package and build a time-series forecasting model. - Create the lag features for you by specifying the autoregression order
auto_order
, the exogenous input orderexog_order
, and the exogenous input delayexog_delay
. - Support multi-step prediction. The package can make multi-step prediction in two different ways: recursive way and direct way.
NARX
model is to build a one-step-ahead-predictive model, and the model will be used recursively to make multi-step prediction (future exogenous input information is needed).DirectAutoRegressor
makes multi-step prediction directly (no future exogenous input information is needed) by specifying the prediction step in the constructor. - Support grid search to tune the hyper-parameters of the base model (cannot do grid search on the orders and delays of the time series model for now).
I developed this package when writing this paper. It is really handy to generate lag features and leverage various regression algorithms provided by sklearn to build non-linear multi-variate time series models. The API can also be used to build deep neural network models to make time-series prediction. The paper used this package to build LSTM models and make multi-step predictions.
The documentation can be found here. The documentation provides the mathematical equations of each model. It is highly recommended to read the documentation before using the model.
fireTS.models.NARX
model is trying to train a one-step-ahead-prediction model
and make multi-step prediction recursively given the future exogenous inputs.
Given the output time series to predict y(t)
and exogenous inputs X(t)
The model will generate target and features as follows:
Target | Features |
---|---|
y(t + 1) | y(t), y(t - 1), ..., y(t - p + 1), X(t - d), X(t - d - 1), ..., X(t - d - q + 1) |
where p is the autogression order auto_order
, q is the exogenous input order exog_order
, d is the exogenous delay exog_delay
.
NARX model can make any step ahead prediction given the future exogenous inputs. To make multi-step prediction, set the step
in the predict
method.
fireTS.models.DirectAutoRegressor
model is trying to train a
multi-step-head-prediction model directly. No future exogenous inputs are
required to make the multi-step prediction.
Given the output time series to predict y(t)
and exogenous inputs X(t)
The model will generate target and features as follows:
Target | Features |
---|---|
y(t + k) | y(t), y(t - 1), ..., y(t - p + 1), X(t - d), X(t - d - 1), ..., X(t - d - q + 1) |
where p is the autogression order auto_order
, q is the exogenous input order exog_order
, d is the exogenous delay exog_delay
, k is the prediction step pred_step
.
Direct autoregressor does not require future exogenous input information to make multi-step prediction. Its predict
method cannot specify prediction step.
NOTE: Only python3 is supported.
It is highly recommended to use pip
to install fireTS
, follow this
link to install pip.
After pip is installed,
pip install fireTS
To get the latest development version,
git clone https://github.com/jxx123/fireTS.git
cd fireTS
pip install -e .
- Use
RandomForestRegressor
as base model to build aNARX
model
from fireTS.models import NARX
from sklearn.ensemble import RandomForestRegressor
import numpy as np
x = np.random.randn(100, 1)
y = np.random.randn(100)
mdl = NARX(RandomForestRegressor(), auto_order=2, exog_order=[2], exog_delay=[1])
mdl.fit(x, y)
ypred = mdl.predict(x, y, step=3)
- Use
RandomForestRegressor
as base model to build aDirectAutoRegressor
model
from fireTS.models import DirectAutoRegressor
from sklearn.ensemble import RandomForestRegressor
import numpy as np
x = np.random.randn(100, 1)
y = np.random.randn(100)
mdl = DirectAutoRegressor(RandomForestRegressor(),
auto_order=2,
exog_order=[2],
exog_delay=[1],
pred_step=3)
mdl.fit(x, y)
ypred = mdl.predict(x, y)
- Usage of grid search
from fireTS.models import NARX
from sklearn.ensemble import RandomForestRegressor
import numpy as np
x = np.random.randn(100, 1)
y = np.random.randn(100)
# DirectAutoRegressor can do grid search as well
mdl = NARX(RandomForestRegressor(), auto_order=2, exog_order=[2], exog_delay=[1])
# Grid search
para_grid = {'n_estimators': [10, 30, 100]}
mdl.grid_search(x, y, para_grid, verbose=2)
# Best hyper-parameters are set after grid search, print the model to see the difference
print(mdl)
# Fit the model and make the prediction
mdl.fit(x, y)
ypred = mdl.predict(x, y, step=3)
The examples folder provides more realistic examples. The example1 and example2 use the data simulated by simglucose pakage to fit time series model and make multi-step prediction.
- What is the difference between
predict
andforecast
?- For example, given a target time series
y(0), y(1), ..., y(9)
to predict and the exogenous input time seriesx(0), x(1), ..., x(9)
, build a NARX modelNARX(RandomForestRegressor(), auto_order=1, exog_order=[1], exog_delay=[0])
. The model can be represented by a functiony(t + 1) = f(y(t), x(t)) + e(t)
. predict(x, y, step=2)
outputs a time series that has the same length as originaly
, and it means the 2-step-ahead prediction at each step, i.e.nan, nan, y_hat(2), y_hat(3), ..., y_hat(9)
. Note thaty_hat(2)
is the 2-step-ahead prediction standing at time 0.y_hat(3)
is the 2-step-ahead prediction standing at time 1, and so on. Another very important note is that predicted valuey_hat(2) = f(y_hat(1), x(1)) = f(f(y(0), x(0)), x(1))
. The prediction uses a perfect future informationx(1)
(since you are currently at time 0).- When
forecast(x, y, step=2)
was called, the output is of length 2, meaning the predicted y in the future 2 steps, i.e.y_hat(10), y_hat(11)
. Here, bothy_hat(10), y_hat(11)
are the predicted values standing at time 9. However,forecast
will NOT use any perfect future information of the exogenous inputx
by default. In fact, the default future exogenous inputsx
are assume to be zeros across the whole prediction horizon. You can provide your own future exogenous input values through the optional argumentX_future
(callforcast(x, y, step=2, X_future=your_X_future)
).
- For example, given a target time series