Saved in:
Bibliographic Details
Main Author: Vergara, Vicente
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.23645
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866917539702898688
author Vergara, Vicente
author_facet Vergara, Vicente
contents We study truncated bilinear forms associated with synchronized kernels \[ K(x,y)=k(ϕ(x),ψ(y)), \] where the singularity is governed by a one-dimensional kernel $k$, while the geometry is encoded by the phases $ϕ$ and $ψ$. The central result of the paper is an architecture of exact reduction, analytic transfer, and geometric recomposition for this class of forms. First, we obtain an exact reduction at the level of pushforward measures and weighted pushforward measures in the level variable. Under absolute-continuity hypotheses, this reduction admits an effective realization in the Lebesgue layer, where control of the pushforward densities yields an abstract operator criterion for feeding estimates obtained in the reduced model back into the original problem. As a first complete realization of this scheme, we transfer to the synchronized setting a one-dimensional sparse domination principle for singular truncations with Dini-smooth kernels. The final geometric recomposition then separates two regimes: a uniform regime, where global consequences follow from quantitative control of the pushforward densities, and a critical regime, where degeneration of the phases near critical values forces a localized output weighted by pullbacks.
format Preprint
id arxiv_https___arxiv_org_abs_2603_23645
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Coarea Reduction, Sparse Transfer, and Geometric Recomposition for Synchronized Singular Forms
Vergara, Vicente
Functional Analysis
Differential Geometry
Primary 42B20. Secondary 28A75, 47G10, 42B25
We study truncated bilinear forms associated with synchronized kernels \[ K(x,y)=k(ϕ(x),ψ(y)), \] where the singularity is governed by a one-dimensional kernel $k$, while the geometry is encoded by the phases $ϕ$ and $ψ$. The central result of the paper is an architecture of exact reduction, analytic transfer, and geometric recomposition for this class of forms. First, we obtain an exact reduction at the level of pushforward measures and weighted pushforward measures in the level variable. Under absolute-continuity hypotheses, this reduction admits an effective realization in the Lebesgue layer, where control of the pushforward densities yields an abstract operator criterion for feeding estimates obtained in the reduced model back into the original problem. As a first complete realization of this scheme, we transfer to the synchronized setting a one-dimensional sparse domination principle for singular truncations with Dini-smooth kernels. The final geometric recomposition then separates two regimes: a uniform regime, where global consequences follow from quantitative control of the pushforward densities, and a critical regime, where degeneration of the phases near critical values forces a localized output weighted by pullbacks.
title Coarea Reduction, Sparse Transfer, and Geometric Recomposition for Synchronized Singular Forms
topic Functional Analysis
Differential Geometry
Primary 42B20. Secondary 28A75, 47G10, 42B25
url https://arxiv.org/abs/2603.23645