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Bibliographic Details
Main Authors: Ganguli, Arkaprabha, Samaddar, Anirban, Kéruzoré, Florian, Ramachandra, Nesar, Bessac, Julie, Madireddy, Sandeep, Constantinescu, Emil
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2602.23518
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author Ganguli, Arkaprabha
Samaddar, Anirban
Kéruzoré, Florian
Ramachandra, Nesar
Bessac, Julie
Madireddy, Sandeep
Constantinescu, Emil
author_facet Ganguli, Arkaprabha
Samaddar, Anirban
Kéruzoré, Florian
Ramachandra, Nesar
Bessac, Julie
Madireddy, Sandeep
Constantinescu, Emil
contents Deep generative models (DGMs) compress high-dimensional data but often entangle distinct physical factors in their latent spaces. We present an auxiliary-variable-guided framework for disentangling representations of thermal Sunyaev-Zel'dovich (tSZ) maps of dark matter halos. We introduce halo mass and concentration as auxiliary variables and apply a lightweight alignment penalty to encourage latent dimensions to reflect these physical quantities. To generate sharp and realistic samples, we extend latent conditional flow matching (LCFM), a state-of-the-art generative model, to enforce disentanglement in the latent space. Our Disentangled Latent-CFM (DL-CFM) model recovers the established mass-concentration scaling relation and identifies latent space outliers that may correspond to unusual halo formation histories. By linking latent coordinates to interpretable astrophysical properties, our method transforms the latent space into a diagnostic tool for cosmological structure. This work demonstrates that auxiliary guidance preserves generative flexibility while yielding physically meaningful, disentangled embeddings, providing a generalizable pathway for uncovering independent factors in complex astronomical datasets.
format Preprint
id arxiv_https___arxiv_org_abs_2602_23518
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Uncovering Physical Drivers of Dark Matter Halo Structures with Auxiliary-Variable-Guided Generative Models
Ganguli, Arkaprabha
Samaddar, Anirban
Kéruzoré, Florian
Ramachandra, Nesar
Bessac, Julie
Madireddy, Sandeep
Constantinescu, Emil
Machine Learning
Deep generative models (DGMs) compress high-dimensional data but often entangle distinct physical factors in their latent spaces. We present an auxiliary-variable-guided framework for disentangling representations of thermal Sunyaev-Zel'dovich (tSZ) maps of dark matter halos. We introduce halo mass and concentration as auxiliary variables and apply a lightweight alignment penalty to encourage latent dimensions to reflect these physical quantities. To generate sharp and realistic samples, we extend latent conditional flow matching (LCFM), a state-of-the-art generative model, to enforce disentanglement in the latent space. Our Disentangled Latent-CFM (DL-CFM) model recovers the established mass-concentration scaling relation and identifies latent space outliers that may correspond to unusual halo formation histories. By linking latent coordinates to interpretable astrophysical properties, our method transforms the latent space into a diagnostic tool for cosmological structure. This work demonstrates that auxiliary guidance preserves generative flexibility while yielding physically meaningful, disentangled embeddings, providing a generalizable pathway for uncovering independent factors in complex astronomical datasets.
title Uncovering Physical Drivers of Dark Matter Halo Structures with Auxiliary-Variable-Guided Generative Models
topic Machine Learning
url https://arxiv.org/abs/2602.23518