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TimeSqueeze: Dynamic Patching for Efficient Time Series Forecasting

Artificial Intelligence 2026-03-13 v1

Abstract

Transformer-based time series foundation models face a fundamental trade-off in choice of tokenization: point-wise embeddings preserve temporal fidelity but scale poorly with sequence length, whereas fixed-length patching improves efficiency by imposing uniform boundaries that may disrupt natural transitions and blur informative local dynamics. In order to address these limitations, we introduce TimeSqueeze, a dynamic patching mechanism that adaptively selects patch boundaries within each sequence based on local signal complexity. TimeSqueeze first applies a lightweight state-space encoder to extract full-resolution point-wise features, then performs content-aware segmentation by allocating short patches to information-dense regions and long patches to smooth or redundant segments. This variable-resolution compression preserves critical temporal structure while substantially reducing the token sequence presented to the Transformer backbone. Specifically for large-scale pretraining, TimeSqueeze attains up to 20x faster convergence and 8x higher data efficiency compared to equivalent point-token baselines. Experiments across long-horizon forecasting benchmarks show that TimeSqueeze consistently outperforms comparable architectures that use either point-wise tokenization or fixed-size patching.

Keywords

Cite

@article{arxiv.2603.11352,
  title  = {TimeSqueeze: Dynamic Patching for Efficient Time Series Forecasting},
  author = {Sravan Kumar Ankireddy and Nikita Seleznev and Nam H. Nguyen and Yulun Wu and Senthil Kumar and Furong Huang and C. Bayan Bruss},
  journal= {arXiv preprint arXiv:2603.11352},
  year   = {2026}
}

Comments

21 pages, 14 figures

R2 v1 2026-07-01T11:15:38.869Z