Geometric Layer-wise Approximation Rates for Deep Networks
Abstract
Depth is widely viewed as a central contributor to the success of deep neural networks, whereas standard neural network approximation theory typically provides guarantees only for the final output and leaves the role of intermediate layers largely unclear. We address this gap by developing a quantitative framework in which depth admits a precise scale-dependent interpretation. Specifically, we design a single shared mixed-activation architecture of fixed width and any prescribed finite depth such that each intermediate readout is itself an approximant to the target function . For with , the approximation error of is controlled by times the modulus of continuity at the geometric scale for all . The estimate reduces to the geometric rate if is -Lipschitz. Our network design is inspired by multigrade deep learning, where depth serves as a progressive refinement mechanism: each new correction targets residual information at a finer scale while the earlier correction terms remain part of the later readouts, yielding a nested architecture that supports adaptive refinement without redesigning the preceding network.
Cite
@article{arxiv.2604.20219,
title = {Geometric Layer-wise Approximation Rates for Deep Networks},
author = {Shijun Zhang and Zuowei Shen and Yuesheng Xu},
journal= {arXiv preprint arXiv:2604.20219},
year = {2026}
}