DeCoP: Enhancing Self-Supervised Time Series Representation with Dependency Controlled Pre-training
Abstract
Modeling dynamic temporal dependencies is a critical challenge in time series pre-training, which evolve due to distribution shifts and multi-scale patterns. This temporal variability severely impairs the generalization of pre-trained models to downstream tasks. Existing frameworks fail to capture the complex interactions of short- and long-term dependencies, making them susceptible to spurious correlations that degrade generalization. To address these limitations, we propose DeCoP, a Dependency Controlled Pre-training framework that explicitly models dynamic, multi-scale dependencies by simulating evolving inter-patch dependencies. At the input level, DeCoP introduces Instance-wise Patch Normalization (IPN) to mitigate distributional shifts while preserving the unique characteristics of each patch, creating a robust foundation for representation learning. At the latent level, a hierarchical Dependency Controlled Learning (DCL) strategy explicitly models inter-patch dependencies across multiple temporal scales, with an Instance-level Contrastive Module (ICM) enhances global generalization by learning instance-discriminative representations from time-invariant positive pairs. DeCoP achieves state-of-the-art results on ten datasets with lower computing resources, improving MSE by 3% on ETTh1 over PatchTST using only 37% of the FLOPs.
Cite
@article{arxiv.2509.14642,
title = {DeCoP: Enhancing Self-Supervised Time Series Representation with Dependency Controlled Pre-training},
author = {Yuemin Wu and Zhongze Wu and Xiu Su and Feng Yang and Hongyan Xu and Xi Lin and Wenti Huang and Shan You and Chang Xu},
journal= {arXiv preprint arXiv:2509.14642},
year = {2025}
}