Geometric stability via information theory

David Ellis; Ehud Friedgut; Guy Kindler; Amir Yehudayoff

doi:https://doi.org/10.19086/da.784

Geometric stability via information theory

David Ellis, Ehud Friedgut, Guy Kindler, Amir Yehudayoff

Weizmann Institute of Science, The Hebrew University of Jerusalem, Technion - Israel Institute of Technology

Research output: Contribution to journal › Article › peer-review

Abstract

The Loomis-Whitney inequality, and the more general Uniform Cover inequality, bound the volume of a body in terms of a product of the volumes of lower-dimensional projections of the body. In this paper, we prove stability versions of these inequalities, showing that when they are close to being tight, the body in question is close in symmetric difference to a box. Our results are best possible up to a constant factor depending upon the dimension alone. Our approach is information theoretic. We use our stability result for the Loomis-Whitney inequality to obtain a stability result for the edge-isoperimetric inequality in the infinite d-dimensional lattice. Namely, we prove that a subset of ℤ^d with small edge-boundary must be close in symmetric difference to a d-dimensional cube. Our bound is, again, best possible up to a constant factor depending upon d alone.

Original language	English
Pages (from-to)	1-28
Number of pages	28
Journal	Discrete Analysis
Volume	10
Issue number	2016
DOIs	https://doi.org/10.19086/da.784
State	Published - 28 Jun 2016

Keywords

Entropy
Information theory
Loomis-Whitney inequality
Projections
Stability

All Science Journal Classification (ASJC) codes

Algebra and Number Theory
Geometry and Topology
Discrete Mathematics and Combinatorics

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https://doi.org/10.19086/da.784

https://arxiv.org/abs/1510.00258v4License: Other

Cite this

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title = "Geometric stability via information theory",

abstract = "The Loomis-Whitney inequality, and the more general Uniform Cover inequality, bound the volume of a body in terms of a product of the volumes of lower-dimensional projections of the body. In this paper, we prove stability versions of these inequalities, showing that when they are close to being tight, the body in question is close in symmetric difference to a box. Our results are best possible up to a constant factor depending upon the dimension alone. Our approach is information theoretic. We use our stability result for the Loomis-Whitney inequality to obtain a stability result for the edge-isoperimetric inequality in the infinite d-dimensional lattice. Namely, we prove that a subset of ℤd with small edge-boundary must be close in symmetric difference to a d-dimensional cube. Our bound is, again, best possible up to a constant factor depending upon d alone.",

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N2 - The Loomis-Whitney inequality, and the more general Uniform Cover inequality, bound the volume of a body in terms of a product of the volumes of lower-dimensional projections of the body. In this paper, we prove stability versions of these inequalities, showing that when they are close to being tight, the body in question is close in symmetric difference to a box. Our results are best possible up to a constant factor depending upon the dimension alone. Our approach is information theoretic. We use our stability result for the Loomis-Whitney inequality to obtain a stability result for the edge-isoperimetric inequality in the infinite d-dimensional lattice. Namely, we prove that a subset of ℤd with small edge-boundary must be close in symmetric difference to a d-dimensional cube. Our bound is, again, best possible up to a constant factor depending upon d alone.

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Geometric stability via information theory

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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