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Model-Preserving Adaptive Rounding

Machine Learning 2025-09-29 v2 Artificial Intelligence

Abstract

The goal of quantization is to produce a compressed model whose output distribution is as close to the original model's as possible. To do this tractably, most quantization algorithms minimize the immediate activation error of each layer as a proxy for the end-to-end error. However, this ignores the effect of future layers, making it a poor proxy. In this work, we introduce Yet Another Quantization Algorithm (YAQA), an adaptive rounding algorithm that directly considers the error at the network's output. YAQA introduces a series of theoretical results that culminate in the first end-to-end error bounds for quantization algorithms. First, we characterize the convergence time of adaptive rounding algorithms via the structure of their Hessian approximations. We then show that the end-to-end error can be bounded by the approximation's cosine similarity to the true Hessian. This admits a natural Kronecker-factored approximation with corresponding near-optimal Hessian sketches. YAQA is provably better than GPTQ/LDLQ and empirically reduces the error by 30%\approx 30\% over these methods. YAQA even achieves a lower error than quantization aware training. This translates to state of the art performance on downstream tasks, all while adding no inference overhead.

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Cite

@article{arxiv.2505.22988,
  title  = {Model-Preserving Adaptive Rounding},
  author = {Albert Tseng and Zhaofeng Sun and Christopher De Sa},
  journal= {arXiv preprint arXiv:2505.22988},
  year   = {2025}
}

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Preprint

R2 v1 2026-07-01T02:47:36.495Z