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Main Authors: Federici, Marco, van Breugel, Boris, Whatmough, Paul, Nagel, Markus
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.04359
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author Federici, Marco
van Breugel, Boris
Whatmough, Paul
Nagel, Markus
author_facet Federici, Marco
van Breugel, Boris
Whatmough, Paul
Nagel, Markus
contents Quantization can drastically increase the efficiency of large language and vision models, but typically incurs an accuracy drop. Recently, function-preserving transforms (e.g. rotations, Hadamard transform, channel-wise scaling) have been successfully applied to reduce post-training quantization error, yet a principled explanation remains elusive. We analyze linear-layer quantization via the signal-to-quantization-noise ratio (SQNR), showing that for uniform integer quantization at a fixed bit width, SQNR decomposes into (i) the concentration of weights and activations (capturing spread and outliers), and (ii) the alignment of their dominant variation directions. This reveals an actionable insight: beyond concentration - the focus of most prior transforms (e.g. rotations or Hadamard) - improving alignment between weight and activation can further reduce quantization error. Motivated by this, we introduce block Concentration-Alignment Transforms (CAT), a lightweight linear transformation that uses a covariance estimate from a small calibration set to jointly improve concentration and alignment, approximately maximizing SQNR. Experiments across several LLMs show that CAT consistently matches or outperforms prior transform-based quantization methods at 4-bit precision, confirming the insights gained in our framework.
format Preprint
id arxiv_https___arxiv_org_abs_2603_04359
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Dissecting Quantization Error: A Concentration-Alignment Perspective
Federici, Marco
van Breugel, Boris
Whatmough, Paul
Nagel, Markus
Machine Learning
Artificial Intelligence
Quantization can drastically increase the efficiency of large language and vision models, but typically incurs an accuracy drop. Recently, function-preserving transforms (e.g. rotations, Hadamard transform, channel-wise scaling) have been successfully applied to reduce post-training quantization error, yet a principled explanation remains elusive. We analyze linear-layer quantization via the signal-to-quantization-noise ratio (SQNR), showing that for uniform integer quantization at a fixed bit width, SQNR decomposes into (i) the concentration of weights and activations (capturing spread and outliers), and (ii) the alignment of their dominant variation directions. This reveals an actionable insight: beyond concentration - the focus of most prior transforms (e.g. rotations or Hadamard) - improving alignment between weight and activation can further reduce quantization error. Motivated by this, we introduce block Concentration-Alignment Transforms (CAT), a lightweight linear transformation that uses a covariance estimate from a small calibration set to jointly improve concentration and alignment, approximately maximizing SQNR. Experiments across several LLMs show that CAT consistently matches or outperforms prior transform-based quantization methods at 4-bit precision, confirming the insights gained in our framework.
title Dissecting Quantization Error: A Concentration-Alignment Perspective
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2603.04359