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Main Authors: Klein, Timon, Kusch, Jonas, Sager, Sebastian, Schnake, Stefan, Schotthöfer, Steffen
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.30033
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author Klein, Timon
Kusch, Jonas
Sager, Sebastian
Schnake, Stefan
Schotthöfer, Steffen
author_facet Klein, Timon
Kusch, Jonas
Sager, Sebastian
Schnake, Stefan
Schotthöfer, Steffen
contents The pursuit of reducing the memory footprint of the self-attention mechanism in multi-headed self attention (MHA) spawned a rich portfolio of methods, e.g., group-query attention (GQA) and multi-head latent attention (MLA). The methods leverage specialized low-rank factorizations across embedding dimensions or attention heads. From the point of view of classical low-rank approximation, these methods are unconventional and raise questions of which objects they really approximate and how to interpret the low-rank behavior of the resulting representations. To answer these questions, this work proposes a generalized view on the weight objects in the self-attention layer and a factorization strategy, which allows us to construct a parameter efficient scheme, called Tucker Attention. Tucker Attention requires an order of magnitude fewer parameters for comparable validation metrics, compared to GQA and MLA, as evaluated in LLM and ViT test cases. Additionally, Tucker Attention~encompasses GQA, MLA, MHA as special cases and is fully compatible with flash-attention and rotary position embeddings (RoPE). This generalization strategy yields insights of the actual ranks achieved by MHA, GQA, and MLA, and further enables simplifications for MLA.
format Preprint
id arxiv_https___arxiv_org_abs_2603_30033
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Tucker Attention: A generalization of approximate attention mechanisms
Klein, Timon
Kusch, Jonas
Sager, Sebastian
Schnake, Stefan
Schotthöfer, Steffen
Machine Learning
Artificial Intelligence
The pursuit of reducing the memory footprint of the self-attention mechanism in multi-headed self attention (MHA) spawned a rich portfolio of methods, e.g., group-query attention (GQA) and multi-head latent attention (MLA). The methods leverage specialized low-rank factorizations across embedding dimensions or attention heads. From the point of view of classical low-rank approximation, these methods are unconventional and raise questions of which objects they really approximate and how to interpret the low-rank behavior of the resulting representations. To answer these questions, this work proposes a generalized view on the weight objects in the self-attention layer and a factorization strategy, which allows us to construct a parameter efficient scheme, called Tucker Attention. Tucker Attention requires an order of magnitude fewer parameters for comparable validation metrics, compared to GQA and MLA, as evaluated in LLM and ViT test cases. Additionally, Tucker Attention~encompasses GQA, MLA, MHA as special cases and is fully compatible with flash-attention and rotary position embeddings (RoPE). This generalization strategy yields insights of the actual ranks achieved by MHA, GQA, and MLA, and further enables simplifications for MLA.
title Tucker Attention: A generalization of approximate attention mechanisms
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2603.30033