Convolutionally Low-Rank Models with Modified Quantile Regression for Interval Time Series Forecasting
Abstract
The quantification of uncertainty in prediction models is crucial for reliable decision-making, yet remains a significant challenge. Interval time series forecasting offers a principled solution to this problem by providing prediction intervals (PIs), which indicates the probability that the true value falls within the predicted range. We consider a recently established point forecasts (PFs) method termed Learning-Based Convolution Nuclear Norm Minimization (LbCNNM), which directly generates multi-step ahead forecasts by leveraging the convolutional low-rankness property derived from training data. While theoretically complete and empirically effective, LbCNNM lacks inherent uncertainty estimation capabilities, a limitation shared by many advanced forecasting methods. To resolve the issue, we modify the well-known Quantile Regression (QR) and integrate it into LbCNNM, resulting in a novel interval forecasting method termed LbCNNM with Modified Quantile Regression (LbCNNM-MQR). In addition, we devise interval calibration techniques to further improve the accuracy of PIs. Extensive experiments on over 100,000 real-world time series demonstrate the superior performance of LbCNNM-MQR.
Cite
@article{arxiv.2604.15791,
title = {Convolutionally Low-Rank Models with Modified Quantile Regression for Interval Time Series Forecasting},
author = {Miaoxuan Zhu and Yi Yu and Yuyang Li and Wei Li and Guangcan Liu},
journal= {arXiv preprint arXiv:2604.15791},
year = {2026}
}