A numerical transcendental method in algebraic geometry: Computation of picard groups and related invariants

Pierre Lairez; Emre Can Sertöz

doi:10.1137/18M122861X

A numerical transcendental method in algebraic geometry: Computation of picard groups and related invariants

Pierre Lairez
, Emre Can Sertöz

École Polytechnique

Max Planck Institute for Mathematics in the Sciences

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

Abstract

Based on high precision computation of periods and lattice reduction techniques, we compute the Picard group of smooth surfaces in P³. As an application, we count the number of rational curves of a given degree lying on each surface. For quartic surfaces we also compute the endomorphism ring of their transcendental lattice. The method applies more generally to the computation of the lattice generated by Hodge cycles of middle dimension on smooth projective hypersurfaces. We demonstrate the method by a systematic study of thousands of quartic surfaces (K3 surfaces) defined by sparse polynomials. The results are only supported by strong numerical evidence, yet the possibility of error is quantified in intrinsic terms, like the degree of curves generating the Picard group.

Original language	English
Pages (from-to)	559-584
Number of pages	26
Journal	SIAM Journal on Applied Algebra and Geometry
Volume	3
Issue number	4
DOIs	https://doi.org/10.1137/18M122861X
Publication status	Published - 1 Jan 2019

Keywords

Algebraic geometry
Hodge theory
Period matrices
Picard groups
Transcendental methods
Variation of Hodge structure

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title = "A numerical transcendental method in algebraic geometry: Computation of picard groups and related invariants",

abstract = "Based on high precision computation of periods and lattice reduction techniques, we compute the Picard group of smooth surfaces in P3. As an application, we count the number of rational curves of a given degree lying on each surface. For quartic surfaces we also compute the endomorphism ring of their transcendental lattice. The method applies more generally to the computation of the lattice generated by Hodge cycles of middle dimension on smooth projective hypersurfaces. We demonstrate the method by a systematic study of thousands of quartic surfaces (K3 surfaces) defined by sparse polynomials. The results are only supported by strong numerical evidence, yet the possibility of error is quantified in intrinsic terms, like the degree of curves generating the Picard group.",

keywords = "Algebraic geometry, Hodge theory, Period matrices, Picard groups, Transcendental methods, Variation of Hodge structure",

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T2 - Computation of picard groups and related invariants

AU - Lairez, Pierre

AU - Sertöz, Emre Can

PY - 2019/1/1

Y1 - 2019/1/1

N2 - Based on high precision computation of periods and lattice reduction techniques, we compute the Picard group of smooth surfaces in P3. As an application, we count the number of rational curves of a given degree lying on each surface. For quartic surfaces we also compute the endomorphism ring of their transcendental lattice. The method applies more generally to the computation of the lattice generated by Hodge cycles of middle dimension on smooth projective hypersurfaces. We demonstrate the method by a systematic study of thousands of quartic surfaces (K3 surfaces) defined by sparse polynomials. The results are only supported by strong numerical evidence, yet the possibility of error is quantified in intrinsic terms, like the degree of curves generating the Picard group.

AB - Based on high precision computation of periods and lattice reduction techniques, we compute the Picard group of smooth surfaces in P3. As an application, we count the number of rational curves of a given degree lying on each surface. For quartic surfaces we also compute the endomorphism ring of their transcendental lattice. The method applies more generally to the computation of the lattice generated by Hodge cycles of middle dimension on smooth projective hypersurfaces. We demonstrate the method by a systematic study of thousands of quartic surfaces (K3 surfaces) defined by sparse polynomials. The results are only supported by strong numerical evidence, yet the possibility of error is quantified in intrinsic terms, like the degree of curves generating the Picard group.

KW - Algebraic geometry

KW - Hodge theory

KW - Period matrices

KW - Picard groups

KW - Transcendental methods

KW - Variation of Hodge structure

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DO - 10.1137/18M122861X

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SN - 2470-6566

VL - 3

SP - 559

EP - 584

JO - SIAM Journal on Applied Algebra and Geometry

JF - SIAM Journal on Applied Algebra and Geometry

IS - 4

ER -

A numerical transcendental method in algebraic geometry: Computation of picard groups and related invariants

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Keywords

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