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Hauptverfasser: Tiblias, Federico, Bigoulaeva, Irina, Niu, Jingcheng, Balloccu, Simone, Gurevych, Iryna
Format: Preprint
Veröffentlicht: 2025
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2510.01025
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author Tiblias, Federico
Bigoulaeva, Irina
Niu, Jingcheng
Balloccu, Simone
Gurevych, Iryna
author_facet Tiblias, Federico
Bigoulaeva, Irina
Niu, Jingcheng
Balloccu, Simone
Gurevych, Iryna
contents The linear representation hypothesis states that language models (LMs) encode concepts as directions in their latent space, forming organized, multidimensional manifolds. Prior work has largely focused on identifying specific geometries for individual features, limiting its ability to generalize. We introduce Supervised Multi-Dimensional Scaling (SMDS), a model-agnostic method for evaluating and comparing competing feature manifold hypotheses. We apply SMDS to temporal reasoning as a case study and find that different features instantiate distinct geometric structures, including circles, lines, and clusters. SMDS reveals several consistent characteristics of these structures: they reflect the semantic properties of the concepts they represent, remain stable across model families and sizes, actively support reasoning, and dynamically reshape in response to contextual changes. Together, our findings shed light on the functional role of feature manifolds, supporting a model of entity-based reasoning in which LMs encode and transform structured representations.
format Preprint
id arxiv_https___arxiv_org_abs_2510_01025
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Hypothesis-Driven Feature Manifold Analysis in LLMs via Supervised Multi-Dimensional Scaling
Tiblias, Federico
Bigoulaeva, Irina
Niu, Jingcheng
Balloccu, Simone
Gurevych, Iryna
Artificial Intelligence
Computation and Language
The linear representation hypothesis states that language models (LMs) encode concepts as directions in their latent space, forming organized, multidimensional manifolds. Prior work has largely focused on identifying specific geometries for individual features, limiting its ability to generalize. We introduce Supervised Multi-Dimensional Scaling (SMDS), a model-agnostic method for evaluating and comparing competing feature manifold hypotheses. We apply SMDS to temporal reasoning as a case study and find that different features instantiate distinct geometric structures, including circles, lines, and clusters. SMDS reveals several consistent characteristics of these structures: they reflect the semantic properties of the concepts they represent, remain stable across model families and sizes, actively support reasoning, and dynamically reshape in response to contextual changes. Together, our findings shed light on the functional role of feature manifolds, supporting a model of entity-based reasoning in which LMs encode and transform structured representations.
title Hypothesis-Driven Feature Manifold Analysis in LLMs via Supervised Multi-Dimensional Scaling
topic Artificial Intelligence
Computation and Language
url https://arxiv.org/abs/2510.01025