This paper investigates approximation-theoretic aspects of the in-context learning capability of the transformers in representing a family of noisy linear dynamical systems. Our first theoretical result establishes an upper bound on the approximation error of multi-layer transformers with respect to an L2-testing loss uniformly defined across tasks. This result demonstrates that transformers with logarithmic depth can achieve error bounds comparable with those of the least-squares estimator. In contrast, our second result establishes a non-diminishing lower bound on the approximation error for a class of single-layer linear transformers, which suggests a depth-separation phenomenon for transformers in the in-context learning of dynamical systems. Moreover, this second result uncovers a critical distinction in the approximation power of single-layer linear transformers when learning from IID versus non-IID data.
@article{arxiv.2502.08136,
title = {In-Context Learning of Linear Dynamical Systems with Transformers: Approximation Bounds and Depth-Separation},
author = {Frank Cole and Yuxuan Zhao and Yulong Lu and Tianhao Zhang},
journal= {arXiv preprint arXiv:2502.08136},
year = {2025}
}
Comments
NeurIPS 2025 camera ready version. Slight change to title and author order from earlier version. Added experiments and acknowledgements section