{AALF}: Almost Always Linear Forecasting
Recent work for time-series forecasting increasingly leverages the high predictive power of Deep Learning models. With this increase in model complexity, however, comes a lack in understanding of the underlying model decision process, which is problematic for safety-critical application scenarios. At the same time, simple, interpretable forecasting methods such as {ARIMA} and {ETS} still perform very well, sometimes on-par with Deep Learning approaches. We argue that using interpretable forecasters leads to good predictions in most cases. However, the forecasting performance can be improved by selecting a Deep Learning method only for few, important predictions, increasing the overall interpretability of the forecasting process. In this context, we propose a novel online model selection framework which learns to identify these predictions. An extensive empirical study on various real-world datasets containing over 3500 individual time-series shows that our selection methodology performs comparable to state-of-the-art online model selection methods in most cases while being significantly more interpretable. We find that almost always choosing a simple autoregressive or exponential smoothing model for forecasting, results in competitive performance, suggesting that the need for opaque black-box models in time-series forecasting might be smaller than recent works would suggest.
- Published in:
Machine Learning - Type:
Article - Authors:
- Year:
2026 - Source:
https://doi.org/10.1007/s10994-026-07020-2
Citation information
: {AALF}: Almost Always Linear Forecasting, Machine Learning, 2026, 115, 3, 55, March, https://doi.org/10.1007/s10994-026-07020-2, Jakobs.Liebig.2026a,
@Article{Jakobs.Liebig.2026a,
author={Jakobs, Matthias; Liebig, Thomas},
title={{AALF}: Almost Always Linear Forecasting},
journal={Machine Learning},
volume={115},
number={3},
pages={55},
month={March},
url={https://doi.org/10.1007/s10994-026-07020-2},
year={2026},
abstract={Recent work for time-series forecasting increasingly leverages the high predictive power of Deep Learning models. With this increase in model complexity, however, comes a lack in understanding of the underlying model decision process, which is problematic for safety-critical application scenarios. At the same time, simple, interpretable forecasting methods such as {ARIMA} and {ETS} still perform...}}