Efficient $k$-Sparse Band–Limited Interpolation with Improved Approximation Ratio
Abstract
We consider the task of interpolating a $k$-sparse band–limited signal from a small collection of noisy time-domain samples. Exploiting a new analytic framework for hierarchical frequency decomposition that performs systematic noise cancellation, we give the first polynomial-time algorithm with a provable $(3+\sqrt{2}+\epsilon)$-approximation guarantee for continuous interpolation. Our method breaks the long-standing $C > 100$ barrier set by the best previous algorithms, sharply reducing the gap to optimal recovery and establishing a new state of the art for high-accuracy band–limited interpolation. We also give a refined ``shrinking-range'' variant that achieves a $(\sqrt{2}+\varepsilon+c)$-approximation on any sub-interval $(1-c)T$ for some $c \in (0,1)$, which gives even higher interpolation accuracy.
Cite
Text
Cao et al. "Efficient $k$-Sparse Band–Limited Interpolation with Improved Approximation Ratio." Advances in Neural Information Processing Systems, 2025.Markdown
[Cao et al. "Efficient $k$-Sparse Band–Limited Interpolation with Improved Approximation Ratio." Advances in Neural Information Processing Systems, 2025.](https://mlanthology.org/neurips/2025/cao2025neurips-efficient/)BibTeX
@inproceedings{cao2025neurips-efficient,
title = {{Efficient $k$-Sparse Band–Limited Interpolation with Improved Approximation Ratio}},
author = {Cao, Yang and Li, Xiaoyu and Song, Zhao and Yang, Chiwun},
booktitle = {Advances in Neural Information Processing Systems},
year = {2025},
url = {https://mlanthology.org/neurips/2025/cao2025neurips-efficient/}
}