Source code for autogluon.timeseries.models.local.naive
from typing import List
import numpy as np
import pandas as pd
from scipy.stats import norm
from autogluon.timeseries.utils.forecast import get_forecast_horizon_index_single_time_series
from .abstract_local_model import AbstractLocalModel
def seasonal_naive_forecast(
time_series: pd.Series, freq: str, prediction_length: int, quantile_levels: List[float], seasonal_period: int
):
forecast_timestamps = get_forecast_horizon_index_single_time_series(
past_timestamps=time_series.index, freq=freq, prediction_length=prediction_length
)
target = time_series.values.ravel()
forecast = {}
if len(target) > seasonal_period and seasonal_period > 1:
indices = [len(target) - seasonal_period + k % seasonal_period for k in range(prediction_length)]
forecast["mean"] = target[indices]
residuals = target[seasonal_period:] - target[:-seasonal_period]
sigma = np.sqrt(np.mean(np.square(residuals)))
num_full_seasons = np.arange(1, prediction_length + 1) // seasonal_period
sigma_per_timestep = sigma * np.sqrt(num_full_seasons + 1)
else:
# Fall back to naive forecast
forecast["mean"] = np.full(shape=[prediction_length], fill_value=target[-1])
residuals = target[1:] - target[:-1]
sigma = np.sqrt(np.mean(np.square(residuals)))
sigma_per_timestep = sigma * np.sqrt(np.arange(1, prediction_length + 1))
for q in quantile_levels:
forecast[str(q)] = forecast["mean"] + norm.ppf(q) * sigma_per_timestep
return pd.DataFrame(forecast, index=forecast_timestamps)
[docs]class NaiveModel(AbstractLocalModel):
"""Baseline model that sets the forecast equal to the last observed value.
Quantiles are obtained by assuming that the residuals follow zero-mean normal distribution, scale of which is
estimated from the empirical distribution of the residuals.
As described in https://otexts.com/fpp3/prediction-intervals.html
"""
allowed_local_model_args = ["seasonal_period"]
@staticmethod
def _predict_with_local_model(
time_series: pd.Series,
freq: str,
prediction_length: int,
quantile_levels: List[float],
local_model_args: dict,
**kwargs,
) -> pd.DataFrame:
return seasonal_naive_forecast(
time_series=time_series,
freq=freq,
prediction_length=prediction_length,
quantile_levels=quantile_levels,
seasonal_period=1,
)
[docs]class SeasonalNaiveModel(AbstractLocalModel):
"""Baseline model that sets the forecast equal to the last observed value from the same season.
Quantiles are obtained by assuming that the residuals follow zero-mean normal distribution, scale of which is
estimated from the empirical distribution of the residuals.
As described in https://otexts.com/fpp3/prediction-intervals.html
Other Parameters
----------------
seasonal_period : int or None, default = None
Number of time steps in a complete seasonal cycle for seasonal models. For example, 7 for daily data with a
weekly cycle or 12 for monthly data with an annual cycle.
When set to None, seasonal_period will be inferred from the frequency of the training data. Can also be
specified manually by providing an integer > 1.
If seasonal_period (inferred or provided) is equal to 1, will fall back to Naive forecast.
Seasonality will also be disabled, if the length of the time series is < seasonal_period.
"""
allowed_local_model_args = ["seasonal_period"]
@staticmethod
def _predict_with_local_model(
time_series: pd.Series,
freq: str,
prediction_length: int,
quantile_levels: List[float],
local_model_args: dict,
**kwargs,
) -> pd.DataFrame:
return seasonal_naive_forecast(
time_series=time_series,
freq=freq,
prediction_length=prediction_length,
quantile_levels=quantile_levels,
seasonal_period=local_model_args["seasonal_period"],
)