FreqLens: Interpretable Frequency Attribution for Time Series Forecasting
Abstract
Time series forecasting models often lack interpretability, limiting their adoption in domains requiring explainable predictions. We propose \textsc{FreqLens}, an interpretable forecasting framework that discovers and attributes predictions to learnable frequency components. \textsc{FreqLens} introduces two key innovations: (1) \emph{learnable frequency discovery} -- frequency bases are parameterized via sigmoid mapping and learned from data with diversity regularization, enabling automatic discovery of dominant periodic patterns without domain knowledge; and (2) \emph{axiomatic frequency attribution} -- a theoretically grounded framework that provably satisfies Completeness, Faithfulness, Null-Frequency, and Symmetry axioms, with per-frequency attributions equivalent to Shapley values. On Traffic and Weather datasets, \textsc{FreqLens} achieves competitive or superior performance while discovering physically meaningful frequencies: all 5 independent runs discover the 24-hour daily cycle (h, 2.5\% error) and 12-hour half-daily cycle (h, 1.6\% error) on Traffic, and weekly cycles ( longer than the input window) on Weather. These results demonstrate genuine frequency-level knowledge discovery with formal theoretical guarantees on attribution quality.
Cite
@article{arxiv.2602.08768,
title = {FreqLens: Interpretable Frequency Attribution for Time Series Forecasting},
author = {Chi-Sheng Chen and Xinyu Zhang and En-Jui Kuo and Guan-Ying Chen and Qiuzhe Xie and Fan Zhang},
journal= {arXiv preprint arXiv:2602.08768},
year = {2026}
}