Battling the Non-stationarity in Time Series Forecasting via Test-time Adaptation

HyunGi Kim; Siwon Kim; Jisoo Mok; Sungroh Yoon

2025 AAAI AAAI 2025

Battling the Non-stationarity in Time Series Forecasting via Test-time Adaptation

Abstract

Abstract Deep Neural Networks have spearheaded remarkable advancements in time series forecasting (TSF), one of the major tasks in time series modeling. Nonetheless, the non-stationarity of time series undermines the reliability of pre-trained source time series forecasters in mission-critical deployment settings. In this study, we introduce a pioneering test-time adaptation framework tailored for TSF (TSF-TTA). TAFAS, the proposed approach to TSF-TTA, flexibly adapts source forecasters to continuously shifting test distributions while preserving the core semantic information learned during pre-training. The novel utilization of partially-observed ground truth and gated calibration module enables proactive, robust, and model-agnostic adaptation of source forecasters. Experiments on diverse benchmark datasets and cutting-edge architectures demonstrate the efficacy and generality of TAFAS, especially in long-term forecasting scenarios that suffer from significant distribution shifts.

🌉 Interdisciplinary Bridge — Artificial Intelligence and Data Science & Analytics and Deep Learning and Machine Learning

🐝 Cross-Pollinator — Artificial Intelligence, Computer Science, Computer Vision, Data Science & Analytics, Deep Learning, Healthcare & Medicine, Interdisciplinary, Knowledge & Reasoning, Machine Learning, Mathematics & Optimization, Natural Language Processing, Reinforcement Learning, Robotics, Security & Privacy, Speech & Audio

Authors

HyunGi Kim , Siwon Kim , Jisoo Mok , Sungroh Yoon

Topics

Artificial Intelligence > Learning Paradigms > Transfer Learning Machine Learning > Application Areas > Domain Adaptation Deep Learning > Architectures > Neural Networks Data Science & Analytics > Methods > Time Series Analysis Machine Learning > Learning Paradigms > Transfer Learning Machine Learning > Learning Types > Transfer Learning Artificial Intelligence > Core AI > Efficient Computing

Keywords

domain adaptation test-time adaptation time series forecasting distribution shift non-stationary datum

Download PDF

Related papers

BEV-TSR: Text-Scene Retrieval in BEV Space for Autonomous Driving 2025

APIRL: Deep Reinforcement Learning for REST API Fuzzing 2025

Anywhere: A Multi-Agent Framework for User-Guided, Reliable, and Diverse Foreground-Conditioned Image Generation 2025

3CAD: A Large-Scale Real-World 3C Product Dataset for Unsupervised Anomaly Detection 2025

Collaborative Learning for 3D Hand-Object Reconstruction and Compositional Action Recognition from Egocentric RGB Videos Using Superquadrics 2025