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Main Authors: Ramesh, Sai-Aakash, Sood, Archit, Corbett, Andrew, Dodwell, Tim
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.27619
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author Ramesh, Sai-Aakash
Sood, Archit
Corbett, Andrew
Dodwell, Tim
author_facet Ramesh, Sai-Aakash
Sood, Archit
Corbett, Andrew
Dodwell, Tim
contents Learning representations that capture both intrinsic data geometry and target-relevant structure remains a fundamental challenge, particularly in settings where data reduction must balance compression with predictive fidelity. While distributional reduction-encompassing joint clustering and dimensionality reduction-offers a principled way to summarize data, its supervised variants remain relatively under-explored, despite the importance of retaining task-relevant signal for downstream prediction and decision-making. We propose Supervised Distributional Reduction (SDR), an algorithm for learning target-aware representations by combining optimal transport with explicit dependence maximization. SDR builds on the Fused Gromov-Wasserstein (FGW) objective to align the relational structure of the input distribution with a set of representative points, while augmenting it with a direct dependence term that encourages the learned embeddings to capture predictive signal more explicitly. This results in compact representations that reflect both geometric structure and supervision. Beyond representation learning, SDR naturally induces a data-dependent, non-stationary geometry that can be leveraged for settings such as Gaussian Process (GP) modelling. By redefining distances through target-aware distributional alignment, SDR enables the construction of adaptive kernels that respond to local variations in both data geometry and supervision, offering an optimal transport-based perspective on non-stationary kernel design.
format Preprint
id arxiv_https___arxiv_org_abs_2605_27619
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Supervised Distributional Reduction via Optimal Transport and Dependence Maximization
Ramesh, Sai-Aakash
Sood, Archit
Corbett, Andrew
Dodwell, Tim
Machine Learning
Artificial Intelligence
Learning representations that capture both intrinsic data geometry and target-relevant structure remains a fundamental challenge, particularly in settings where data reduction must balance compression with predictive fidelity. While distributional reduction-encompassing joint clustering and dimensionality reduction-offers a principled way to summarize data, its supervised variants remain relatively under-explored, despite the importance of retaining task-relevant signal for downstream prediction and decision-making. We propose Supervised Distributional Reduction (SDR), an algorithm for learning target-aware representations by combining optimal transport with explicit dependence maximization. SDR builds on the Fused Gromov-Wasserstein (FGW) objective to align the relational structure of the input distribution with a set of representative points, while augmenting it with a direct dependence term that encourages the learned embeddings to capture predictive signal more explicitly. This results in compact representations that reflect both geometric structure and supervision. Beyond representation learning, SDR naturally induces a data-dependent, non-stationary geometry that can be leveraged for settings such as Gaussian Process (GP) modelling. By redefining distances through target-aware distributional alignment, SDR enables the construction of adaptive kernels that respond to local variations in both data geometry and supervision, offering an optimal transport-based perspective on non-stationary kernel design.
title Supervised Distributional Reduction via Optimal Transport and Dependence Maximization
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2605.27619