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Main Authors: Cooper, John, Diakonikolas, Ilias, Ma, Mingchen, Sala, Frederic
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.08859
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author Cooper, John
Diakonikolas, Ilias
Ma, Mingchen
Sala, Frederic
author_facet Cooper, John
Diakonikolas, Ilias
Ma, Mingchen
Sala, Frederic
contents Hybrid sequence models--combining Transformer and state-space model layers--seek to gain the expressive versatility of attention as well as the computational efficiency of state-space model layers. Despite burgeoning interest in hybrid models, we lack a basic understanding of the settings where--and underlying mechanisms through which--they offer benefits over their constituent models. In this paper, we study this question, focusing on a broad family of core synthetic tasks. For this family of tasks, we prove the existence of fundamental limitations for non-hybrid models. Specifically, any Transformer or state-space model that solves the underlying task requires either a large number of parameters or a large working memory. On the other hand, for two prototypical tasks within this family--namely selective copying and associative recall--we construct hybrid models of small size and working memory that provably solve these tasks, thus achieving the best of both worlds. Our experimental evaluation empirically validates our theoretical findings. Importantly, going beyond the settings in our theoretical analysis, we empirically show that learned--rather than constructed--hybrids outperform non-hybrid models with up to 6x as many parameters. We additionally demonstrate that hybrid models exhibit stronger length generalization and out-of-distribution robustness than non-hybrids.
format Preprint
id arxiv_https___arxiv_org_abs_2603_08859
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Expressivity-Efficiency Tradeoffs for Hybrid Sequence Models
Cooper, John
Diakonikolas, Ilias
Ma, Mingchen
Sala, Frederic
Machine Learning
Hybrid sequence models--combining Transformer and state-space model layers--seek to gain the expressive versatility of attention as well as the computational efficiency of state-space model layers. Despite burgeoning interest in hybrid models, we lack a basic understanding of the settings where--and underlying mechanisms through which--they offer benefits over their constituent models. In this paper, we study this question, focusing on a broad family of core synthetic tasks. For this family of tasks, we prove the existence of fundamental limitations for non-hybrid models. Specifically, any Transformer or state-space model that solves the underlying task requires either a large number of parameters or a large working memory. On the other hand, for two prototypical tasks within this family--namely selective copying and associative recall--we construct hybrid models of small size and working memory that provably solve these tasks, thus achieving the best of both worlds. Our experimental evaluation empirically validates our theoretical findings. Importantly, going beyond the settings in our theoretical analysis, we empirically show that learned--rather than constructed--hybrids outperform non-hybrid models with up to 6x as many parameters. We additionally demonstrate that hybrid models exhibit stronger length generalization and out-of-distribution robustness than non-hybrids.
title Expressivity-Efficiency Tradeoffs for Hybrid Sequence Models
topic Machine Learning
url https://arxiv.org/abs/2603.08859