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Main Authors: Mozer, Michael C., Siddiqui, Shoaib Ahmed, Liu, Rosanne
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.17121
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author Mozer, Michael C.
Siddiqui, Shoaib Ahmed
Liu, Rosanne
author_facet Mozer, Michael C.
Siddiqui, Shoaib Ahmed
Liu, Rosanne
contents Transformers encode structure in sequences via an expanding contextual history. However, their purely feedforward architecture fundamentally limits dynamic state tracking. State tracking -- the iterative updating of latent variables reflecting an evolving environment -- involves inherently sequential dependencies that feedforward networks struggle to maintain. Consequently, feedforward models push evolving state representations deeper into their layer stack with each new input step, rendering information inaccessible in shallow layers and ultimately exhausting the model's depth. While this depth limit can be bypassed by dynamic depth models and by explicit or latent thinking that externalizes state representations, these solutions are computationally and memory inefficient. In this article, we argue that temporally extended cognition requires refocusing from explicit thought traces to implicit activation dynamics via recurrent architectures. We introduce a taxonomy of recurrent and continuous-thought transformer architectures, categorizing them by their recurrence axis (depth versus step) and their ratio of input tokens to recurrence steps. Finally, we outline promising research directions, including enhanced state-space models and coarse-grained recurrence, to better integrate state tracking into modern foundation models.
format Preprint
id arxiv_https___arxiv_org_abs_2604_17121
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle The Topological Trouble With Transformers
Mozer, Michael C.
Siddiqui, Shoaib Ahmed
Liu, Rosanne
Machine Learning
Artificial Intelligence
Transformers encode structure in sequences via an expanding contextual history. However, their purely feedforward architecture fundamentally limits dynamic state tracking. State tracking -- the iterative updating of latent variables reflecting an evolving environment -- involves inherently sequential dependencies that feedforward networks struggle to maintain. Consequently, feedforward models push evolving state representations deeper into their layer stack with each new input step, rendering information inaccessible in shallow layers and ultimately exhausting the model's depth. While this depth limit can be bypassed by dynamic depth models and by explicit or latent thinking that externalizes state representations, these solutions are computationally and memory inefficient. In this article, we argue that temporally extended cognition requires refocusing from explicit thought traces to implicit activation dynamics via recurrent architectures. We introduce a taxonomy of recurrent and continuous-thought transformer architectures, categorizing them by their recurrence axis (depth versus step) and their ratio of input tokens to recurrence steps. Finally, we outline promising research directions, including enhanced state-space models and coarse-grained recurrence, to better integrate state tracking into modern foundation models.
title The Topological Trouble With Transformers
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2604.17121