DOCSLIB.ORG

Qt5dt9t63z.Pdf

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Qt5dt9t63z.Pdf UC Berkeley UC Berkeley Electronic Theses and Dissertations Title Real Algebraic Geometry in Convex Optimization Permalink https://escholarship.org/uc/item/5dt9t63z Author Vinzant, Cynthia Leslie Publication Date 2011 Peer reviewed|Thesis/dissertation eScholarship.org Powered by the California Digital Library University of California Real Algebraic Geometry in Convex Optimization by Cynthia Leslie Vinzant A dissertation submitted in partial satisfaction of the requirements for the degree of Doctor of Philosophy in Mathematics in the Graduate Division of the University of California, BERKELEY Committee in charge: Professor Bernd Sturmfels, Chair Professor David Eisenbud Professor Alper Atamt¨urk Spring 2011 Real Algebraic Geometry in Convex Optimization Copyright 2011 by Cynthia Leslie Vinzant 1 Abstract Real Algebraic Geometry in Convex Optimization by Cynthia Leslie Vinzant Doctor of Philosophy in Mathematics University of California, BERKELEY Professor Bernd Sturmfels, Chair In the past twenty years, a strong interplay has developed between convex optimization and algebraic geometry. Algebraic geometry provides necessary tools to analyze the behavior of solutions, the geometry of feasible sets, and to develop new relaxations for hard non-convex problems. On the other hand, numerical solvers for convex optimization have led to new fast algorithms in real algebraic geometry. In Chapter 1 we introduce some of the necessary background in convex optimization and real algebraic geometry and discuss some of the important results and questions in their intersection. One of the biggest of which is: when can a convex closed semialgebraic set be the feasible set of a semidefinite program and how can one construct such a representation? In Chapter 2, we explore the consequences of an ideal I ⊂ R[x1; : : : ; xn] having a real radical initial ideal, both for the geometry of the real variety of I and as an application to sums of squares representations of polynomials. We show that if inw(I) is real radical for a vector w in the tropical variety, then w is in the logarithmic set of its real variety. We also give algebraic sufficient conditions for w to be in the logarithmic limit set of a more general n semialgebraic set. If, in addition, w 2 (R>0) , then the corresponding quadratic module is stable, which has consequences for problems in polynomial optimization. In particular, if n P 2 inw(I) is real radical for some w 2 (R>0) then R[x1; : : : ; xn] + I is stable. This provides a method for checking the conditions for stability given by Powers and Scheiderer. In Chapter 3, we examine fundamental objects in convex algebraic geometry, such as def- inite determinantal representations and sums of squares, in the special case of plane quartics. A smooth quartic curve in the complex projective plane has 36 inequivalent representations as a symmetric determinant of linear forms and 63 representations as a sum of three squares. These correspond to Cayley octads and Steiner complexes respectively. We present exact algorithms for computing these objects from the 28 bitangents. This expresses Vinnikov quartics as spectrahedra and positive quartics as Gram matrices. We explore the geometry of Gram spectrahedra and discuss methods for computing determinantal representations. Interwoven are many examples and an exposition of much of the 19th century theory of plane quartics. 2 In Chapter 4, we study real algebraic curves that control interior point methods in linear programming. The central curve of a linear program is an algebraic curve specified by linear and quadratic constraints arising from complementary slackness. It is the union of the various central paths for minimizing or maximizing the cost function over any region in the associated hyperplane arrangement. We determine the degree, arithmetic genus and defining prime ideal of the central curve, thereby answering a question of Bayer and Lagarias. These invariants, along with the degree of the Gauss image of the curve, are expressed in terms of the matroid of the input matrix. Extending work of Dedieu, Malajovich and Shub, this yields an instance-specific bound on the total curvature of the central path, a quantity relevant for interior point methods. The global geometry of central curves is studied in detail. Chapter 5 has two parts. In the first, we study the kth symmetric trigonometric mo- ment curve and its convex hull, the Barvinok-Novik orbitope. In 2008, Barvinok and Novik introduce these objects and show that there is some threshold so that for two points on S1 with arclength below this threshold the line segment between their lifts to the curve form an edge on the Barvinok-Novik orbitope and for points with arclength above this threshold, their lifts do not form an edge. They also give a lower bound for this threshold and con- jecture that this bound is tight. Results of Smilansky prove tightness for k = 2. Here we prove this conjecture for all k. In the second part, we discuss the convex hull of a general parametrized curve. These convex hulls can be written as spectrahedral shadows and, as we shall demonstrate, one can compute and effectively describe their faces. i To my family. ii Contents List of Figures iv List of Tables v 1 Introduction 1 1.1 Convexity, Optimization, and Spectrahedra . .1 1.2 Real Algebraic Geometry and Sums of Squares . .4 1.3 Convex Algebraic Geometry . .6 1.3.1 Central Curves . .6 1.3.2 Determinantal Representations and Hyperbolic Polynomials . .7 1.3.3 Convex Hulls of Semialgebraic Sets . .8 1.3.4 Gram Matrices and Sums of Squares . .9 1.3.5 SDPs and Polynomial Optimization . 10 2 Real Radical Initial Ideals 11 2.1 Preliminaries: Initial Ideals and Sums of Squares . 11 2.2 Real Tropical Geometry . 15 2.3 Stability of Sums of Squares modulo an Ideal . 22 2.4 Connections to Compactification . 24 2.5 Connections to Puiseux Series . 26 2.6 Computation . 27 3 Quartic Curves and their Bitangents 31 3.1 History and Motivation . 31 3.2 Computing a Symmetric Determinantal Representation from Contact Curves 35 3.3 Cayley Octads and the Cremona Action . 37 3.4 Sums of Three Squares and Steiner Complexes . 41 3.5 The Gram spectrahedron . 46 3.6 Definite Representations of Vinnikov Quartics . 50 3.7 Real and Definite Determinantal Representations . 54 3.8 A Tropical Example . 59 iii 4 The Central Curve of a Linear Program 62 4.1 Background and Definitions . 62 4.2 Plane Curves . 67 4.3 Concepts from Matroid Theory . 71 4.4 Equations defining the central curve . 74 4.5 The Gauss Curve of the Central Path . 79 4.6 Global Geometry of the Central Curve . 84 4.7 Conclusion . 89 5 Convex Hulls of Curves 93 5.1 The Barvinok-Novik orbitope . 93 5.1.1 Trigonometric Moment Curves . 93 5.1.2 Curves Dipping Behind Facets . 95 5.1.3 Understanding the Facet fxk = 1g .................... 96 5.1.4 Proof of Theorem 5.1.1 . 100 5.1.5 Useful Trigonometric Identities . 101 5.2 The Convex Hull of a Parametrized Curve . 102 5.2.1 Facial structure . 102 5.2.2 The Algebraic Boundary . 104 5.2.3 The Boundary of a Face-Vertex Set . 105 5.2.4 Testing Faces . 106 5.2.5 A Four-Dimensional Example . 107 Bibliography 109 iv List of Figures 1.1 A spectrahedron and a non-exposed vertex of its shadow. .3 1.2 Hyperbolic hypersurfaces bounding spectrahedra. .8 3.1 The Edge quartic and some of its 28 bitangents . 33 3.2 A quartic Vinnikov curve from Example 3.6.1 and four contact cubics . 55 3.3 Degeneration of a Vinnikov quartic into four lines. 60 3.4 A tropical quartic with its seven bitangents. 61 3.5 A tropical quartic with two of its contact cubics . 61 4.1 The central curve of six lines for two choices of the cost function . 63 4.2 The DTZ snake with 6 constraints. On the left, a global view of the polygon and its central curve with the line y2 = 1 appearing as part of the curve. On the right a close-up of the central path and its inflection points. 66 4.3 The degree-6 central path of a planar 7-gon in the affine charts fy0 = 1g and fy2 = 1g. Every line passing through [0 : −b2 : b1] intersects the curve in 6 real points, showing the real curve to be 3 completely-nested ovals. 68 4.4 Correspondence of vertices and analytic centers in the two projections of a primal-dual central curve. Here both curves are plane cubics. 88 4.5 A degree 5 primal central curve in R3 and its degree 4 dual central curve in R2......................................... 91 5.1 Projection of the curve C3 onto the facet fx3 = 1g of its convex hull. The 0 tangent vector C3(t0) + C3(t0) for t0 = 2π=5 is shown in red. 96 5.2 The curve Ck−1 with simplices Pk and Qk for k = 3 (left) and k = 4 (right). 97 π 5.3 Here are two examples of the graphs of fj;k(θ). Note that fj;k( 2k−1 t) has roots f1;:::; 2k − 1gnf2j; 2k − 1 − 2jg, all of multiplicity one. 100 5.4 Edge-vertex set of a curve in R3.......................... 103 5.5 Edge-vertex set of the curve (5.12) in R4..................... 108 v List of Tables 3.1 The six types of smooth quartics in the real projective plane. 33 3.2 Statistics for semidefinite programming over Gram spectrahedra. 50 3.3 The real and definite of LMRs of the six types of smooth quartics. 56 vi Acknowledgments I would first like to thank my advisor, Bernd Sturmfels, for teaching me so much and giving me constant guidance and support.
Load more

Recommended publications
  • [Math.AG] 1 Nov 2005 Where Uoopimgop Hscntuto Ensahlmrhcperio Holomorphic a Defines Construction This Group
    A COMPACTIFICATION OF M3 VIA K3 SURFACES MICHELA ARTEBANI Abstract. S. Kond¯odefined a birational period map from the moduli space of genus three curves to a moduli space of degree four polarized K3 surfaces. In this paper we extend the period map to a surjective morphism on a suitable compactification of M3 and describe its geometry. Introduction 14 Let V =| OP2 (4) |=∼ P be the space of plane quartics and V0 be the open subvariety of smooth curves. The degree four cyclic cover of the plane branched along a curve C ∈ V0 is a K3 surface equipped with an order four non-symplectic automorphism group. This construction defines a holomorphic period map: P0 : V0 −→ M, where V0 is the geometric quotient of V0 by the action of P GL(3) and M is a moduli space of polarized K3 surfaces. In [15] S. Kond¯oshows that P0 gives an isomorphism between V0 and the com- plement of two irreducible divisors Dn, Dh in M. Moreover, he proves that the generic points in Dn and Dh correspond to plane quartics with a node and to smooth hyperelliptic genus three curves respectively. The moduli space M is an arithmetic quotient of a six dimensional complex ball, hence a natural compactification is given by the Baily-Borel compactification M∗ (see [1]). On the other hand, geometric invariant theory provides a compact pro- jective variety V containing V0 as a dense subset, given by the categorical quotient of the semistable locus in V for the natural action of P GL(3). In this paper we prove that the map P0 can be extended to a holomorphic surjective map P : V −→M∗ on the blowing-up V of V in the point v0 corresponding to the orbit of double arXiv:math/0511031v1 [math.AG] 1 Nov 2005 e conics.
    [Show full text]
  • Shadow of a Cubic Surface
    Faculteit B`etawetenschappen Shadow of a cubic surface Bachelor Thesis Rein Janssen Groesbeek Wiskunde en Natuurkunde Supervisors: Dr. Martijn Kool Departement Wiskunde Dr. Thomas Grimm ITF June 2020 Abstract 3 For a smooth cubic surface S in P we can cast a shadow from a point P 2 S that does not lie on one of the 27 lines of S onto a hyperplane H. The closure of this shadow is a smooth quartic curve. Conversely, from every smooth quartic curve we can reconstruct a smooth cubic surface whose closure of the shadow is this quartic curve. We will also present an algorithm to reconstruct the cubic surface from the bitangents of a quartic curve. The 27 lines of S together with the tangent space TP S at P are in correspondence with the 28 bitangents or hyperflexes of the smooth quartic shadow curve. Then a short discussion on F-theory is given to relate this geometry to physics. Acknowledgements I would like to thank Martijn Kool for suggesting the topic of the shadow of a cubic surface to me and for the discussions on this topic. Also I would like to thank Thomas Grimm for the suggestions on the applications in physics of these cubic surfaces. Finally I would like to thank the developers of Singular, Sagemath and PovRay for making their software available for free. i Contents 1 Introduction 1 2 The shadow of a smooth cubic surface 1 2.1 Projection of the first polar . .1 2.2 Reconstructing a cubic from the shadow . .5 3 The 27 lines and the 28 bitangents 9 3.1 Theorem of the apparent boundary .
    [Show full text]
  • Combination of Cubic and Quartic Plane Curve
    IOSR Journal of Mathematics (IOSR-JM) e-ISSN: 2278-5728,p-ISSN: 2319-765X, Volume 6, Issue 2 (Mar. - Apr. 2013), PP 43-53 www.iosrjournals.org Combination of Cubic and Quartic Plane Curve C.Dayanithi Research Scholar, Cmj University, Megalaya Abstract The set of complex eigenvalues of unistochastic matrices of order three forms a deltoid. A cross-section of the set of unistochastic matrices of order three forms a deltoid. The set of possible traces of unitary matrices belonging to the group SU(3) forms a deltoid. The intersection of two deltoids parametrizes a family of Complex Hadamard matrices of order six. The set of all Simson lines of given triangle, form an envelope in the shape of a deltoid. This is known as the Steiner deltoid or Steiner's hypocycloid after Jakob Steiner who described the shape and symmetry of the curve in 1856. The envelope of the area bisectors of a triangle is a deltoid (in the broader sense defined above) with vertices at the midpoints of the medians. The sides of the deltoid are arcs of hyperbolas that are asymptotic to the triangle's sides. I. Introduction Various combinations of coefficients in the above equation give rise to various important families of curves as listed below. 1. Bicorn curve 2. Klein quartic 3. Bullet-nose curve 4. Lemniscate of Bernoulli 5. Cartesian oval 6. Lemniscate of Gerono 7. Cassini oval 8. Lüroth quartic 9. Deltoid curve 10. Spiric section 11. Hippopede 12. Toric section 13. Kampyle of Eudoxus 14. Trott curve II. Bicorn curve In geometry, the bicorn, also known as a cocked hat curve due to its resemblance to a bicorne, is a rational quartic curve defined by the equation It has two cusps and is symmetric about the y-axis.
    [Show full text]
  • Tropical Curves
    Tropical Curves Nathan Pflueger 24 February 2011 Abstract A tropical curve is a graph with specified edge lengths, some of which may be infinite. Various facts and attributes about algebraic curves have analogs for tropical curves. In this article, we focus on divisors and linear series, and prove the Riemann-Roch formula for divisors on tropical curves. We describe two ways in which algebraic curves may be transformed into tropical curves: by aboemas and by specialization on arithmetic surfaces. We discuss how the study of linear series on tropical curves can be used to obtain results about linear series on algebraic curves, and summarize several recent applications. Contents 1 Introduction 2 2 From curves to graphs 3 2.1 Amoebas of plane curves . .3 2.2 Curves over the field of Puiseux series . .4 2.3 Specialization . .5 3 Metric graphs and tropical curves 6 4 Divisors and linear equivalence on tropical curves 9 4.1 The Riemann-Roch criterion . 12 4.2 Tropical Riemann-Roch . 14 5 Tropical plane curves 17 5.1 Tropical algebra and tropical projective space . 17 5.2 Tropical curves in R2 ................................... 18 5.3 Calculation of the genus . 23 5.4 Stable intersection and the tropical B´ezouttheorem . 24 5.5 Classical B´ezoutfrom tropical B´ezout . 29 5.6 Enumerative geometry of tropical plane curves . 31 6 Tropical curves via specialization 32 6.1 The specialization map and specialization lemma . 32 6.2 The canonical divisor of a graph is canonical . 34 6.3 A tropical proof of the Brill-Noether theorem . 34 1 1 Introduction The origins of tropical geometry lie in the study of tropical algebra, whose basic object is the set R [ {−∞} equipped with the operations x ⊕ y = max(x; y) and x ⊗ y = x + y.
    [Show full text]
  • Foundations of Algebraic Geometry Class 41
    FOUNDATIONS OF ALGEBRAIC GEOMETRY CLASS 41 RAVI VAKIL CONTENTS 1. Normalization 1 2. Extending maps to projective schemes over smooth codimension one points: the “clear denominators” theorem 5 Welcome back! Let's now use what we have developed to study something explicit — curves. Our motivating question is a loose one: what are the curves, by which I mean nonsingular irreducible separated curves, finite type over a field k? In other words, we'll be dealing with geometry, although possibly over a non-algebraically closed field. Here is an explicit question: are all curves (say reduced, even non-singular, finite type over given k) isomorphic? Obviously not: some are affine, and some (such as P1) are not. So to simplify things — and we'll further motivate this simplification in Class 42 — are all projective curves isomorphic? Perhaps all nonsingular projective curves are isomorphic to P1? Once again the answer is no, but the proof is a bit subtle: we've defined an invariant, the genus, and shown that P1 has genus 0, and that there exist nonsingular projective curves of non-zero genus. Are all (nonsingular) genus 0 curves isomorphic to P1? We know there exist nonsingular genus 1 curves (plane cubics) — is there only one? If not, “how many” are there? In order to discuss interesting questions like these, we'll develop some theory. We first show a useful result that will help us focus our attention on the projective case. 1. NORMALIZATION I now want to tell you how to normalize a reduced Noetherian scheme, which is roughly how best to turn a scheme into a normal scheme.
    [Show full text]
  • Triple Conformal Geometric Algebra for Cubic Plane Curves
    Received 13 February 2017; Revised 3 July 2018 (revised preprint with corrections) ; Accepted 22 August 2017 DOI: 10.1002/mma.4597 is revision 18 Sep 2017, published in Mathematical Methods in the Applied Sciences, 41(11)4088–4105, 30 July 2018, Special Issue: ENGAGE SPECIAL ISSUE PAPER Triple Conformal Geometric Algebra for Cubic Plane Curves Robert Benjamin Easter1 | Eckhard Hitzer2 1Bangkok, Thailand. Email: [email protected] Summary 2College of Liberal Arts, International The Triple Conformal Geometric Algebra (TCGA) for the Euclidean R2-plane ex- Christian University, 3-10-2 Osawa, 181-8585 Mitaka, Tokyo, Japan. Email: tends CGA as the product of three orthogonal CGAs, and thereby the representation [email protected] of geometric entities to general cubic plane curves and certain cyclidic (or roulette) Communicated by: Dietmar Hildenbrand MSC Primary: 15A66; quartic, quintic, and sextic plane curves. The plane curve entities are 3-vectors that MSC Secondary: 14H50; 53A30; linearize the representation of non-linear curves, and the entities are inner product Correspondence null spaces (IPNS) with respect to all points on the represented curves. Each IPNS Eckhard Hitzer, College of Liberal Arts, entity also has a dual geometric outer product null space (OPNS) form. Orthogonal or International Christian University, 3-10-2 conformal (angle-preserving) operations (as versors) are valid on all TCGA entities Osawa, 181-8585 Mitaka, Tokyo, Japan. Email: [email protected] for inversions in circles, reflections in lines, and, by compositions thereof, isotropic dilations from a given center point, translations, and rotations around arbitrary points in the plane. A further dimensional extension of TCGA, also provides a method for anisotropic dilations.
    [Show full text]
  • Limits of Pluri–Tangent Planes to Quartic Surfaces Ciro Ciliberto and Thomas Dedieu
    Limits of pluri–tangent planes to quartic surfaces Ciro Ciliberto and Thomas Dedieu Abstract. We describe, for various degenerations S → ∆ of quartic K3 surfaces over the complex unit disk (e.g., to the union of four general planes, and to a general Kummer surface), the limits ∗ as t ∈ ∆ tends to 0 of the Severi varieties Vδ(St), parametrizing irreducible δ-nodal plane sections of St. We give applications of this to (i) the counting of plane nodal curves through base points in special position, (ii) the irreducibility of Severi varieties of a general quartic surface, and (iii) the monodromy of the universal family of rational curves on quartic K3 surfaces. Contents 1 Conventions 4 2 Limit linear systems and limit Severi varieties 4 3 Auxiliary results 10 4 Degeneration to a tetrahedron 11 5 Other degenerations 28 6 Kummer quartic surfaces in P3 30 7 Degeneration to a Kummer surface 33 8 Plane quartics curves through points in special position 41 9 Application to the irreducibility of Severi varieties and to the monodromy action 46 Introduction Our objective in this paper is to study the following: Question A Let f : S → ∆ be a projective family of surfaces of degree d in P3, with S a smooth −1 threefold, and ∆ the complex unit disc (usually called a degeneration of the general St := f (t), for t 6= 0, which is a smooth surface, to the central fibre S0, which is in general supposed to be singular). What are the limits of tangent, bitangent, and tritangent planes to St, for t 6=0, as t tends to 0? Similar questions make sense also for degenerations of plane curves, and we refer to [25, pp.
    [Show full text]
  • Geometry of Algebraic Curves
    Geometry of Algebraic Curves Lectures delivered by Joe Harris Notes by Akhil Mathew Fall 2011, Harvard Contents Lecture 1 9/2 x1 Introduction 5 x2 Topics 5 x3 Basics 6 x4 Homework 11 Lecture 2 9/7 x1 Riemann surfaces associated to a polynomial 11 x2 IOUs from last time: the degree of KX , the Riemann-Hurwitz relation 13 x3 Maps to projective space 15 x4 Trefoils 16 Lecture 3 9/9 x1 The criterion for very ampleness 17 x2 Hyperelliptic curves 18 x3 Properties of projective varieties 19 x4 The adjunction formula 20 x5 Starting the course proper 21 Lecture 4 9/12 x1 Motivation 23 x2 A really horrible answer 24 x3 Plane curves birational to a given curve 25 x4 Statement of the result 26 Lecture 5 9/16 x1 Homework 27 x2 Abel's theorem 27 x3 Consequences of Abel's theorem 29 x4 Curves of genus one 31 x5 Genus two, beginnings 32 Lecture 6 9/21 x1 Differentials on smooth plane curves 34 x2 The more general problem 36 x3 Differentials on general curves 37 x4 Finding L(D) on a general curve 39 Lecture 7 9/23 x1 More on L(D) 40 x2 Riemann-Roch 41 x3 Sheaf cohomology 43 Lecture 8 9/28 x1 Divisors for g = 3; hyperelliptic curves 46 x2 g = 4 48 x3 g = 5 50 1 Lecture 9 9/30 x1 Low genus examples 51 x2 The Hurwitz bound 52 2.1 Step 1 . 53 2.2 Step 10 ................................. 54 2.3 Step 100 ................................ 54 2.4 Step 2 .
    [Show full text]
  • Arxiv:Math/0403245V1 [Math.AG] 15 Mar 2004 H Osblt Oatn Hssho.Tescn Uhrtha Author Second the School
    A NEW MODEL FOR THE THETA DIVISOR OF THE CUBIC THREEFOLD MICHELA ARTEBANI, REMKE KLOOSTERMAN, AND MARCO PACINI Abstract. In this paper we give a birational model for the theta divisor of the intermediate Jacobian of a generic cubic threefold X. We use the standard realization of X as a conic bundle and a 4−dimensional family of plane quartics which are totally tangent to the discriminant quintic curve of such a conic bundle structure. The additional data of an even theta characteristic on the curves in the family gives us a model for the theta divisor. 1. Introduction Most of the notions mentioned in this introduction are defined in Sections 2 (curves), 3 (surfaces) and 6 (threefolds). In this paper we give a new birational model for the theta divisor of the intermediate Jacobian of a generic cubic threefold X. In [10, Section 4] a birational model for the theta divisor is given in terms of linear systems of skew cubics on hyperplane sections of X. We give a model in terms of even theta characteristics on plane quartics. Consider the triple (S,p,D), with S a smooth cubic surface, p a point on S, not on any line of S and D a double six on S. We can associate to such a triple a smooth plane quartic C together with a bitangent b and an Aronhold set A containing b. Moreover, we can recover (S,p,D) from the triple (C,b,A). This observation is the main ingredient of our construction. We try to extend this correspondence as far as possible.
    [Show full text]
  • Quartic Del Pezzo Surfaces Over Function Fields of Curves
    QUARTIC DEL PEZZO SURFACES OVER FUNCTION FIELDS OF CURVES BRENDAN HASSETT AND YURI TSCHINKEL 1. Introduction The geometry of spaces of rational curves of low degree on Fano threefolds is a very active area of algebraic geometry. One of the main goals is to understand the Abel-Jacobi morphism from the base of a space of such curves to the intermediate Jacobian of the threefold. For instance, does a given space of curves dominate the intermediate Jacobian? If so, what are the fibers of this morphism? Does it give the maximal rationally connected (MRC) quotient? Representative results in this direction are available for: • cubic threefolds [HRS05, JHS, IM00, MT01]; • Fano threefolds of genus six and degree 10 in P7 [DIM12]; • Fano threefolds of genus seven and degree 12 in P8 [IM07]; • moduli of vector bundles [Cas04]|this case makes clear that one cannot always expect the morphism to the intermediate Jacobian to give the MRC fibration. At the same time, del Pezzo fibrations π : X! P1 are equally in- teresting geometrically. Moreover, the special case where the rational curves happen to be sections of π is particularly important for arith- metic applications. It is a major open problem to determine whether or not sections exist over a non-closed ground field. Of course, the Tsen-Lang theorem gives sections when the ground field is algebraically closed. Even when there are rigid sections, these are typically defined over extensions of large degree. However, suppose that the space of sections of fixed height is ratio- nally connected over the intermediate Jacobian IJ(X ).
    [Show full text]
  • Monsters and Moonshine
    Monsters and Moonshine lieven le bruyn 2012 universiteit antwerpen neverendingbooks.org CONTENTS 1. Monsters :::::::::::::::::::::::::::::::::::: 4 1.1 The Scottish solids..............................4 1.2 The Scottish solids hoax...........................4 1.3 Conway’s M13 game.............................8 1.4 The 15-puzzle groupoid (1/2).........................9 1.5 The 15-puzzle groupoid (2/2)......................... 11 1.6 Conway’s M13-groupoid (1/2)........................ 14 1.7 Mathieu’s blackjack (1/3)........................... 16 1.8 Mathieu’s blackjack (2/3)........................... 18 1.9 Mathieu’s blackjack (3/3)........................... 20 1.10 Conway’s M13 groupoid (2/2)........................ 22 1.11 Olivier Messiaen and Mathieu 12 ....................... 24 1.12 Galois’ last letter............................... 26 1.13 Arnold’s trinities (1/2)............................ 28 1.14 The buckyball symmetries.......................... 32 1.15 Arnold’s trinities (2/2)............................ 37 1.16 Klein’s dessins d’enfants and the buckyball................. 39 1.17 The buckyball curve.............................. 42 1.18 The ”uninteresting” case p = 5 ........................ 45 1.19 Tetra lattices.................................. 46 1.20 Who discovered the Leech lattice (1/2).................... 47 1.21 Who discovered the Leech lattice (2/2).................... 50 1.22 Sporadic simple games............................ 53 1.23 Monstrous frustrations............................ 57 1.24 What does the monster
    [Show full text]
  • Equivariant Degenerations of Plane Curve Orbits
    Equivariant Degenerations of Plane Curve Orbits Mitchell Lee, Anand Patel, Dennis Tseng March 26, 2019 Abstract In a series of papers, Aluffi and Faber computed the degree of the GL3 orbit closure of an arbitrary plane curve. We attempt to generalize this to the equivariant setting by studying how orbits degenerate under some natural specializations, yielding a fairly complete picture in the case of plane quartics. 1 Introduction Let V be an r + 1-dimensional vector space, and let F 2 Symd V _ be a non-zero degree d homogeneous form d _ d _ on V . F naturally produces two varieties, OF ⊂ Sym V and POF ⊂ P Sym V , namely the GLr+1-orbit closures of F and [F ] respectively. Basic questions about the relationship between the geometry of POF and the geometry of hypersurface fF = 0g remain unanswered. Consider, for example, the enumerative problem of computing the degree of POF . The analysis of the degrees of these orbit closures was carried out for the first two cases r = 1; 2 in a series of remarkable papers by Aluffi and Faber [AF93a, AF93b, AF00a, AF00c, AF00b, AF10a, AF10b]. For instance, Aluffi and Faber's computation in the special case r = 2; d = 4 of quartic plane curves yields the enumerative consequence: In a general 6-dimensional linear system of quartic curves, a general genus 3 curve arises 14280 times. When fF = 0g is a hyperplane arrangement, the degree of POF was studied by [Tzi08, Li18]. One can interpret the calculation of the degree of POF as computing the fundamental class [POF ] 2 • d _ A (P Sym V ).
    [Show full text]