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Main Authors: Batra, Arnesh, Gumber, Arush, Khandelwal, Aniket, Khemani, Jashn, Gupta, Anubha
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.23033
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author Batra, Arnesh
Gumber, Arush
Khandelwal, Aniket
Khemani, Jashn
Gupta, Anubha
author_facet Batra, Arnesh
Gumber, Arush
Khandelwal, Aniket
Khemani, Jashn
Gupta, Anubha
contents Foundational Models pretrained on huge amount of data learn representations that evolve across depth, forming a hierarchy of embeddings with distinct semantic content and geometric structure. Contrary to the widespread practice of using only the final layer or shallow mixtures, we show that task-relevant information is distributed non-monotonically across layers and cannot be recovered by naïve aggregation. Through a geometric and empirical study across multiple modalities, we show that effective transfer depends on identifying which layers encode task-discriminative structure and how their embeddings are geometrically organized. We introduce Layer-wise Optimal Embedding Selection (LOES), a constructive spectral method that identifies task-discriminative subspaces by minimizing residual error under orthogonality and isotropy constraints. To align fine-tuning with this selection principle, we further propose Geometric Regularization Loss (GeoReg), which enforces a simplicial structure on class manifolds and stabilizes representation geometry during fine-tuning. Across a wide range of architectures, depths, modalities, and data regimes, LOES consistently outperforms standard baselines, with gains that grow as model depth increases. Beyond accuracy, our method reveals how semantic factors are distributed across layers, thereby enabling cross-lingual and cross-modal interpretability analyses. Together, our results provide strong evidence that layerwise embedding geometry is not incidental but central to how deep models represent and transfer knowledge.
format Preprint
id arxiv_https___arxiv_org_abs_2605_23033
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Uncovering the Latent Potential of Deep Intermediate Representations
Batra, Arnesh
Gumber, Arush
Khandelwal, Aniket
Khemani, Jashn
Gupta, Anubha
Machine Learning
Artificial Intelligence
Foundational Models pretrained on huge amount of data learn representations that evolve across depth, forming a hierarchy of embeddings with distinct semantic content and geometric structure. Contrary to the widespread practice of using only the final layer or shallow mixtures, we show that task-relevant information is distributed non-monotonically across layers and cannot be recovered by naïve aggregation. Through a geometric and empirical study across multiple modalities, we show that effective transfer depends on identifying which layers encode task-discriminative structure and how their embeddings are geometrically organized. We introduce Layer-wise Optimal Embedding Selection (LOES), a constructive spectral method that identifies task-discriminative subspaces by minimizing residual error under orthogonality and isotropy constraints. To align fine-tuning with this selection principle, we further propose Geometric Regularization Loss (GeoReg), which enforces a simplicial structure on class manifolds and stabilizes representation geometry during fine-tuning. Across a wide range of architectures, depths, modalities, and data regimes, LOES consistently outperforms standard baselines, with gains that grow as model depth increases. Beyond accuracy, our method reveals how semantic factors are distributed across layers, thereby enabling cross-lingual and cross-modal interpretability analyses. Together, our results provide strong evidence that layerwise embedding geometry is not incidental but central to how deep models represent and transfer knowledge.
title Uncovering the Latent Potential of Deep Intermediate Representations
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2605.23033