Saved in:
Bibliographic Details
Main Authors: Fedorov, Lev, Sander, Michaël E., Elie, Romuald, Marion, Pierre, Laurière, Mathieu
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2601.21942
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866914291595083776
author Fedorov, Lev
Sander, Michaël E.
Elie, Romuald
Marion, Pierre
Laurière, Mathieu
author_facet Fedorov, Lev
Sander, Michaël E.
Elie, Romuald
Marion, Pierre
Laurière, Mathieu
contents Transformers have revolutionized deep learning across various domains but understanding the precise token dynamics remains a theoretical challenge. Existing theories of deep Transformers with layer normalization typically predict that tokens cluster to a single point; however, these results rely on deterministic weight assumptions, which fail to capture the standard initialization scheme in Transformers. In this work, we show that accounting for the intrinsic stochasticity of random initialization alters this picture. More precisely, we analyze deep Transformers where noise arises from the random initialization of value matrices. Under diffusion scaling and token-wise RMS normalization, we prove that, as the number of Transformer layers goes to infinity, the discrete token dynamics converge to an interacting-particle system on the sphere where tokens are driven by a \emph{common} matrix-valued Brownian noise. In this limit, we show that initialization noise prevents the collapse to a single cluster predicted by deterministic models. For two tokens, we prove a phase transition governed by the interaction strength and the token dimension: unlike deterministic attention flows, antipodal configurations become attracting with positive probability. Numerical experiments confirm the predicted transition, reveal that antipodal formations persist for more than two tokens, and demonstrate that suppressing the intrinsic noise degrades accuracy.
format Preprint
id arxiv_https___arxiv_org_abs_2601_21942
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Clustering in Deep Stochastic Transformers
Fedorov, Lev
Sander, Michaël E.
Elie, Romuald
Marion, Pierre
Laurière, Mathieu
Machine Learning
Transformers have revolutionized deep learning across various domains but understanding the precise token dynamics remains a theoretical challenge. Existing theories of deep Transformers with layer normalization typically predict that tokens cluster to a single point; however, these results rely on deterministic weight assumptions, which fail to capture the standard initialization scheme in Transformers. In this work, we show that accounting for the intrinsic stochasticity of random initialization alters this picture. More precisely, we analyze deep Transformers where noise arises from the random initialization of value matrices. Under diffusion scaling and token-wise RMS normalization, we prove that, as the number of Transformer layers goes to infinity, the discrete token dynamics converge to an interacting-particle system on the sphere where tokens are driven by a \emph{common} matrix-valued Brownian noise. In this limit, we show that initialization noise prevents the collapse to a single cluster predicted by deterministic models. For two tokens, we prove a phase transition governed by the interaction strength and the token dimension: unlike deterministic attention flows, antipodal configurations become attracting with positive probability. Numerical experiments confirm the predicted transition, reveal that antipodal formations persist for more than two tokens, and demonstrate that suppressing the intrinsic noise degrades accuracy.
title Clustering in Deep Stochastic Transformers
topic Machine Learning
url https://arxiv.org/abs/2601.21942