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1. Verfasser: Andersen, Madelyn
Format: Preprint
Veröffentlicht: 2021
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Online-Zugang:https://arxiv.org/abs/2112.03885
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author Andersen, Madelyn
author_facet Andersen, Madelyn
contents Graphons are symmetric measurable functions that arise from a sequence of graphs. A graphon variety is the a set of all graphons defined by a condition of the form $t(g, W) = 0$ for a fixed quantum graph $g$, where $t(.,.)$ is the homomorphism density and a quantum graph is a formal linear combination of multigraphs. Using a method of representing graphs as polynomials, we construct an epimorphism from the space of quantum graphs to a subring of the complex polynomial ring that is invariant under permutations of variables. When graphons are of finite rank, we demonstrate that an analog of the "ideal" inverse in Algebraic Geometry is an ideal in our polynomial representation. Defining an algebraic kernel set using kernel varieties, we demonstrate that we can call such sets closed under the Zariski Topology. We determine several ties to Algebraic Geometry as a result of utilizing finite rank kernels and discover that a weaker version of Hilbert's Nullstellensatz applies to kernel zero-sets with respect to homomorphism density. Throughout, we examine the connection between Algebraic Geometry and Graphon Theory.
format Preprint
id arxiv_https___arxiv_org_abs_2112_03885
institution arXiv
publishDate 2021
record_format arxiv
spellingShingle Finite rank kernel varieties: A variant of Hilbert's Nullstellensatz for graphons and applications to Hadamard matrices
Andersen, Madelyn
Algebraic Geometry
Combinatorics
Graphons are symmetric measurable functions that arise from a sequence of graphs. A graphon variety is the a set of all graphons defined by a condition of the form $t(g, W) = 0$ for a fixed quantum graph $g$, where $t(.,.)$ is the homomorphism density and a quantum graph is a formal linear combination of multigraphs. Using a method of representing graphs as polynomials, we construct an epimorphism from the space of quantum graphs to a subring of the complex polynomial ring that is invariant under permutations of variables. When graphons are of finite rank, we demonstrate that an analog of the "ideal" inverse in Algebraic Geometry is an ideal in our polynomial representation. Defining an algebraic kernel set using kernel varieties, we demonstrate that we can call such sets closed under the Zariski Topology. We determine several ties to Algebraic Geometry as a result of utilizing finite rank kernels and discover that a weaker version of Hilbert's Nullstellensatz applies to kernel zero-sets with respect to homomorphism density. Throughout, we examine the connection between Algebraic Geometry and Graphon Theory.
title Finite rank kernel varieties: A variant of Hilbert's Nullstellensatz for graphons and applications to Hadamard matrices
topic Algebraic Geometry
Combinatorics
url https://arxiv.org/abs/2112.03885