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Real Solutions to Equations from Geometry [Pehme köide]

  • Formaat: Paperback / softback, 199 pages, kaal: 394 g
  • Sari: University Lecture Series
  • Ilmumisaeg: 30-Sep-2011
  • Kirjastus: American Mathematical Society
  • ISBN-10: 0821853317
  • ISBN-13: 9780821853313
Teised raamatud teemal:
Real Solutions to Equations from GeometrySuurem pilt
  • Formaat: Paperback / softback, 199 pages, kaal: 394 g
  • Sari: University Lecture Series
  • Ilmumisaeg: 30-Sep-2011
  • Kirjastus: American Mathematical Society
  • ISBN-10: 0821853317
  • ISBN-13: 9780821853313
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9780821853313.html
Märksõnad:
Understanding, finding, or even deciding on the existence of real solutions to a system of equations is a difficult problem with many applications outside of mathematics. While it is hopeless to expect much in general, we know a surprising amount about these questions for systems which possess additional structure often coming from geometry.

This book focuses on equations from toric varieties and Grassmannians. Not only is much known about these, but such equations are common in applications. There are three main themes: upper bounds on the number of real solutions, lower bounds on the number of real solutions, and geometric problems that can have all solutions be real. The book begins with an overview, giving background on real solutions to univariate polynomials and the geometry of sparse polynomial systems. The first half of the book concludes with fewnomial upper bounds and with lower bounds to sparse polynomial systems. The second half of the book begins by sampling some geometric problems for which all solutions can be real, before devoting the last five chapters to the Shapiro Conjecture, in which the relevant polynomial systems have only real solutions.
Preface ix
Chapter 1 Overview
1(12)
1.1 Introduction
2(1)
1.2 Polyhedral bounds
3(1)
1.3 Upper bounds
4(1)
1.4 The Wronski map and the Shapiro Conjecture
5(3)
1.5 Lower bounds
8(5)
Chapter 2 Real Solutions to Univariate Polynomials
13(12)
2.1 Descartes's rule of signs
13(3)
2.2 Sturm's Theorem
16(3)
2.3 A topological proof of Sturm's Theorem
19(6)
Chapter 3 Sparse Polynomial Systems
25(12)
3.1 Polyhedral bounds
26(1)
3.2 Geometric interpretation of sparse polynomial systems
27(2)
3.3 Proof of Kushnirenko's Theorem
29(4)
3.4 Facial systems and degeneracies
33(4)
Chapter 4 Toric Degenerations and Kushnirenko's Theorem
37(12)
4.1 Kushnirenko's Theorem for a simplex
37(2)
4.2 Regular subdivisions and toric degenerations
39(5)
4.3 Kushnirenko's Theorem via toric degenerations
44(3)
4.4 Polynomial systems with only real solutions
47(2)
Chapter 5 Fewnomial Upper Bounds
49(12)
5.1 Khovanskii's fewnomial bound
49(5)
5.2 Kushnirenko's Conjecture
54(2)
5.3 Systems supported on a circuit
56(5)
Chapter 6 Fewnomial Upper Bounds from Gale Dual Polynomial Systems
61(16)
6.1 Gale duality for polynomial systems
62(4)
6.2 New fewnomial bounds
66(8)
6.3 Dense fewnomials
74(3)
Chapter 7 Lower Bounds for Sparse Polynomial Systems
77(14)
7.1 Polynomial systems as fibers of maps
78(2)
7.2 Orientability of real toric varieties
80(4)
7.3 Degree from foldable triangulations
84(5)
7.4 Open problems
89(2)
Chapter 8 Some Lower Bounds for Systems of Polynomials
91(14)
8.1 Polynomial systems from posets
91(5)
8.2 Sagbi degenerations
96(4)
8.3 Incomparable chains, factoring polynomials, and gaps
100(5)
Chapter 9 Enumerative Real Algebraic Geometry
105(16)
9.1 3264 real conics
105(4)
9.2 Some geometric problems
109(7)
9.3 Schubert Calculus
116(5)
Chapter 10 The Shapiro Conjecture for Grassmannians
121(12)
10.1 The Wronski map and Schubert Calculus
122(2)
10.2 Asymptotic form of the Shapiro Conjecture
124(6)
10.3 Grassmann duality
130(3)
Chapter 11 The Shapiro Conjecture for Rational Functions
133(14)
11.1 Nets of rational functions
133(4)
11.2 Schubert induction for rational functions and nets
137(4)
11.3 Rational functions with prescribed coincidences
141(6)
Chapter 12 Proof of the Shapiro Conjecture for Grassmannians
147(14)
12.1 Spaces of polynomials with given Wronskian
148(4)
12.2 The Gaudin model
152(2)
12.3 The Bethe Ansatz for the Gaudin model
154(3)
12.4 Shapovalov form and the proof of the Shapiro Conjecture
157(4)
Chapter 13 Beyond the Shapiro Conjecture for the Grassmannian
161(12)
13.1 Transversality and the Discriminant Conjecture
161(3)
13.2 Maximally inflected curves
164(3)
13.3 Degree of Wronski maps and beyond
167(3)
13.4 The Secant Conjecture
170(3)
Chapter 14 The Shapiro Conjecture Beyond the Grassmannian
173(16)
14.1 The Shapiro Conjecture for the orthogonal Grassmannian
173(2)
14.2 The Shapiro Conjecture for the Lagrangian Grassmannian
175(4)
14.3 The Shapiro Conjecture for flag manifolds
179(1)
14.4 The Monotone Conjecture
180(6)
14.5 The Monotone Secant Conjecture
186(3)
Bibliography 189(6)
Index of Notation 195(2)
Index 197
Frank Sottile is at Texas A&M University, College Station, TX