Integrable Hamiltonian Systems: Geometry, Topology, Classification

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ISBN: 9780415298056 | 0415298059
Cover: Hardcover
Copyright: 2/25/2004

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Integrable Hamiltonian systems have been of growing interest over the past 30 years and represent one of the most intriguing and mysterious classes of dynamical systems. This book explores the topology of integrable systems and the general theory underlying their qualitative properties, singularites, and topological invariants.The authors, both of whom have contributed significantly to the field, develop the classification theory for integrable systems with two degrees of freedom. This theory allows one to distinguish such systems up to two natural equivalence relations: the equivalence of the associated foliation into Liouville tori and the usual orbital equaivalence. The authors show that in both cases, one can find complete sets of invariants that give the solution of the classification problem.The first part of the book systematically presents the general construction of these invariants, including many examples and applications. In the second part, the authors apply the general methods of the classification theory to the classical integrable problems in rigid body dynamics and describe their topological portraits, bifurcations of Liouville tori, and local and global topological invariants. They show how the classification theory helps find hidden isomorphisms between integrable systems and present as an example their proof that two famous systems--the Euler case in rigid body dynamics and the Jacobi problem of geodesics on the ellipsoid--are orbitally equivalent.Integrable Hamiltonian Systems: Geometry, Topology, Classification offers a unique opportunity to explore important, previously unpublished results and acquire generally applicable techniques and tools that enable you to work with a broad class of integrable systems.

Preface

xiii

Basic Notions

(48)

Linear Symplectic Geometry

(3)

Symplectic and Poisson Manifolds

(7)

Cotangent Bundles

(1)

The Complex Space Cn and Its Complex Submanifolds. Kahler Manifolds

(1)

Orbits of Coadjoint Representation

(5)

The Darboux Theorem

(3)

Liouville Integrable Hamiltonian Systems. The Liouville Theorem

(7)

Non-resonant and Resonant Systems

(1)

Rotation Number

(3)

The Momentum Mapping of an Integrable System and Its Bifurcation Diagram

(2)

Non-degenerate Critical Points of the Momentum Mapping

(19)

The Case of Two Degrees of Freedom

(3)

Bott Integrals from the Viewpoint of the Four-Dimensional Symplectic Manifold

(7)

Non-degenerate Singularities in the Case of Many Degrees of Freedom

(3)

Types of Non-degenerate Singularities in the Multidimensional Case

(6)

Main Types of Equivalence of Dynamical Systems

(3)

The Topology of Foliations on Two-Dimensional Surfaces Generated by Morse Functions

(80)

Simple Morse Functions

(2)

Reeb Graph of a Morse Function

(1)

Notion of an Atom

(2)

Simple Atoms

(5)

The Case of Minimum and Maximum. The Atom A

(1)

The Case of an Orientable Saddle. The Atom B

(1)

The Case of a Non-orientable Saddle. The Atom B

(1)

The Classification of Simple Atoms

(2)

Simple Molecules

(9)

Notion of a Simple Molecule

(1)

Realization Theorem

(1)

Examples of Simple Morse Functions and Simple Molecules

(4)

The Classification of Minimal Simple Morse Functions on Surfaces of Low Genus

(4)

Complicated Atoms

(4)

Classification of Atoms

(23)

Classification Problem

(1)

Algorithm of Enumeration of Atoms

(1)

Algorithm of Recognition of Identical Atoms

(1)

Atoms and f-Graphs

(5)

Oriented Atoms and Subgroups in the Group Z * Z2

(2)

Representation of Atoms as Immersions of Graphs into the Plane

(1)

Atoms as Cell Decompositions of Two-Dimensional Closed Surfaces

(1)

Table of Atoms of Low Complexity

(1)

Mirror-like Atoms

(11)

Symmetry Groups of Oriented Atoms and the Universal Covering Tree

(20)

Symmetries of f-Graphs

(1)

The Universal Covering Tree over f-Graphs. An f-Graph as a Quotient Space of the Universal Tree

(3)

The Correspondence between f-Graphs and Subgroups in Z * Z2

(1)

The Graph J of the Symmetry Group of an f-Graph. Totally Symmetric f-Graphs

100

(5)

The List of Totally Symmetric Planar Atoms. Examples of Totally Symmetric Atoms of Genus g > 0

105

(7)

Atoms as Surfaces of Constant Negative Curvature

112

(3)

Notion of a Molecule

115

(5)

Approximation of Complicated Molecules by Simple Ones

120

(4)

Classification of Morse-Smale Flows on Two-Dimensional Surfaces by Means of Atoms and Molecules

124

(5)

Rough Liouville Equivalence of Integrable Systems with Two Degrees of Freedom

129

(30)

Classification of Non-degenerate Critical Submanifolds on Isoenergy 3-Surfaces

129

(6)

The Topological Structure of a Neighborhood of a Singular Leaf

135

(7)

Topologically Stable Hamiltonian Systems

142

(4)

Example of a Topologically Unstable Integrable System

146

(1)

2-Atoms and 3-Atoms

147

(5)

Classification of 3-Atoms

152

(1)

3-Atoms as Bifurcations of Liouville Tori

153

(1)

The Molecule of an Integrable System

154

(2)

Complexity of Integrable Systems

156

(3)

Liouville Equivalence of Integrable Systems with Two Degrees of Freedom

159

(36)

Admissible Coordinate Systems on the Boundary of a 3-Atom

159

(7)

Gluing Matrices and Superfluous Frames

166

(2)

Invariants (Numerical Marks) r, e, and n

168

(3)

Marks ri and ei

168

(1)

Marks nk and Families in a Molecule

169

(2)

The Marked Molecule is a Complete Invariant of Liouville Equivalence

171

(1)

The Influence of the Orientation

172

(2)

Change of Orientation of an Edge of a Molecule

172

(1)

Change of Orientation on a 3-Manifold Q

173

(1)

Change of Orientation of a Hamiltonian Vector Field

174

(1)

Realization Theorem

174

(3)

Simple Examples of Molecules

177

(7)

Hamiltonian Systems with Critical Klein Bottles

184

(3)

Topological Obstructions to Integrability of Hamiltonian Systems with Two Degrees of Freedom

187

(8)

The Class (M)

187

(1)

The Class (H)

188

(1)

The Class (Q)

188

(1)

The Class (W) of Graph-Manifolds

189

(1)

The Class (H) of Manifolds Related to Hamiltonians with Tame Integrals

190

(1)

The Coincidence of the Four Classes of 3-Manifields

190

(5)

Orbital Classification of Integrable Systems with Two Degrees of Freedom

195

(16)

Rotation Function and Rotation Vector

195

(4)

Reduction of the Three-Dimensional Orbital Classification to the Two-Dimensional Classification up to Conjugacy

199

(8)

Transversal Sections

199

(2)

Poincare' Flow and Poincare' Hamiltonian

201

(3)

Reduction Theorem

204

(3)

General Concept of Constructing Orbital Invariants of Integrable Hamiltonian Systems

207

(4)

Classification of Hamiltonian Flows on Two-Dimensional Surfaces up to Topological Conjugacy

211

(28)

Invariants of a Hamiltonian System on a 2-Atom

211

(11)

Λ-Invariant

212

(6)

Δ-Invariant and Z-Invariant

218

(4)

Classification of Hamiltonian Flows with One Degree of Freedom up to Topological Conjugacy on Atoms

222

(4)

Classification of Hamiltonian Flows on 2-Atoms with Involution up to Topological Conjugacy

226

(2)

The Pasting-Cutting Operation

228

(6)

Description of the Sets of Admissible Δ-Invariants and Z-Invariants

234

(5)

Smooth Conjugacy of Hamiltonian Flows on Two-Dimensional Surfaces

239

(16)

Constructing Smooth Invariants on 2-Atoms

239

(9)

Theorem of Classification of Hamiltonian Flows on Atoms up to Smooth Conjugacy

248

(7)

Orbital Classification of Integrable Hamiltonian Systems with Two Degrees of Freedom. The Second Step

255

(44)

Superfluous t-Frame of a Molecule (Topological Case). The Main Lemma on t-Frames

256

(7)

The Group of Transformations of Transversal Sections. Pasting-Cutting Operation

263

(4)

The Action of GP on the Set of Superfluous t-Frames

267

(1)

Three General Principles for Constructing Invariants

268

(1)

First General Principle

268

(1)

Second General Principle

269

(1)

Third General Principle

269

(1)

Admissible Superfluous t-Frames and a Realization Theorem

269

(9)

Realization of a Frame on an Atom

269

(4)

Realization of a Frame on an Edge of a Molecule

273

(3)

Realization of a Frame on the Whole Molecule

276

(2)

Construction of Orbital Invariants in the Topological Case. A t-Molecule

278

(8)

The R-Invariant and the Index of a System on an Edge

278

(2)

b-Invariant (on the Radicals of a Molecule)

280

(2)

Λ-Invariant

282

(1)

Δ Z [Θ]-Invariant

283

(2)

Final Definition of a t-Molecule for an Integrable System

285

(1)

Theorem on the Topological Orbital Classification of Integrable Systems with Two Degrees of Freedom

286

(5)

A Particular Case: Simple Integrable Systems

291

(1)

Smooth Orbital Classification

292

(7)

Liouville Classification of Integrable Systems with Two Degrees of Freedom in Four-Dimensional Neighborhoods of Singular Points

299

(74)

l-Type of a Four-Dimensional Singularity

299

(5)

The Loop Molecule of a Four-Dimensional Singularity

304

(2)

Center-Center Case

306

(2)

Center-Saddle Case

308

(5)

Saddle-Saddle Case

313

(26)

The Structure of a Singular Leaf

313

(5)

Cl-Type of a Singularity

318

(4)

The List of Saddle-Saddle Singularities of Small Complexity

322

(17)

Almost Direct Product Representation of a Four-Dimensional Singularity

339

(9)

Proof of the Classification Theorems

348

(2)

Proof of Theorem 9.3

348

(1)

Proof of Theorem 9.4 (Realization Theorem)

349

(1)

Focus-Focus Case

350

(13)

The Structure of a Singular Leaf of Focus-Focus Type

350

(3)

Classification of Focus-Focus Singularities

353

(3)

Model Example of a Focus-Focus Singularity and the Realization Theorem

356

(2)

The Loop Molecule and Monodromy Group of a Focus-Focus Singularity

358

(5)

Almost Direct Product Representation for Multidimensional Non-degenerate Singularities of Liouville Foliations

363

(10)

Methods of Calculation of Topological Invariants of Integrable Hamiltonian Systems

373

(36)

General Scheme for Topological Analysis of the Liouville Foliation

373

(4)

Momentum Mapping

373

(1)

Construction of the Bifurcation Diagram

374

(1)

Verification of the Non-degeneracy Condition

374

(1)

Description of the Atoms of the System

375

(1)

Construction of the Molecule of the System on a Given Energy Level

376

(1)

Computation of Marks

377

(1)

Methods for Computing Marks

377

(1)

The Loop Molecule Method

378

(4)

List of Typical Loop Molecules

382

(4)

Loop Molecules of Regular Points of the Bifurcation Diagram

382

(2)

Loop Molecules of Non-degenerate Singularities

384

(2)

The Structure of the Liouville Foliation for Typical Degenerate Singularities

386

(3)

Typical Loop Molecules Corresponding to Degenerate One-Dimensional Orbits

389

(6)

Computation of r- and e-Marks by Means of Rotation Functions

395

(3)

Computation of the n-Mark by Means of Rotation Functions

398

(4)

Relationship Between the Marks of the Molecule and the Topology of Q3

402

(7)

Integrable Geodesic Flows on Two-Dimensional Surfaces

409

(68)

Statement of the Problem

409

(3)

Topological Obstructions to Integrability of Geodesic Flows on Two-Dimensional Surfaces

412

(4)

Two Examples of Integrable Geodesic Flows

416

(4)

Surfaces of Revolution

416

(2)

Liouville Metrics

418

(2)

Riemannian Metrics Whose Geodesic Flows are Integrable by Means of Linear or Quadratic Integrals. Local Theory

420

(14)

Some General Properties of Polynomial Integrals of Geodesic Flows. Local Theory

420

(3)

Riemannian Metrics Whose Geodesic Flows Admit a Linear Integral. Local Theory

423

(1)

Riemannian Metrics Whose Geodesic Flows Admit a Quadratic Integral. Local Theory

424

(10)

Linearly and Quadratically Integrable Geodesic Flows on Closed Surfaces

434

(43)

The Torus

434

(13)

The Klein Bottle

447

(10)

The Sphere

457

(15)

The Projective Plane

472

(5)

Liouville Classification of Integrable Geodesic Flows on Two-Dimensional Surfaces

477

(44)

The Torus

477

(14)

The Klein Bottle

491

(9)

Quadratically Integrable Geodesic Flow on the Klein Bottle

491

(5)

Linearly Integrable Geodesic Flows on the Klein Bottle

496

(2)

Quasi-Linearly Integrable Geodesic Flows on the Klein Bottle

498

(1)

Quasi-Quadratically Integrable Geodesic Flows on the Klein Bottle

498

(2)

The Sphere

500

(15)

Quadratically Integrable Geodesic Flows on the Sphere

500

(10)

Linearly Integrable Geodesic Flows on the Sphere

510

(5)

The Projective Plane

515

(6)

Quadratically Integrable Geodesic Flows on the Projective Plane

515

(3)

Linearly Integrable Geodesic Flows on the Projective Plane

518

(3)

Orbital Classification of Integrable Geodesic Flows on Two-Dimensional Surfaces

521

(30)

Case of the Torus

521

(11)

Flows with Simple Bifurcations (Atoms)

521

(9)

Flows with Complicated Bifurcations (Atoms)

530

(2)

Case of the Sphere

532

(3)

Examples of Integrable Geodesic Flows on the Sphere

535

(7)

The Triaxial Ellipsoid

535

(4)

The Standard Sphere

539

(2)

The Poisson Sphere

541

(1)

Non-triviality of Orbital Equivalence Classes and Metrics with Closed Geodesics

542

(9)

The Topology of Liouville Foliations in Classical Integrable Cases in Rigid Body Dynamics

551

(96)

Integrable Cases in Rigid Body Dynamics

551

(9)

Topological Type of Isoenergy 3-Surfaces

560

(20)

The Topology of the Isoenergy Surface and the Bifurcation Diagram

560

(3)

Euler Case

563

(2)

Lagrange Case

565

(4)

Kovalevskaya Case

569

(2)

Zhukovskii Case

571

(3)

Goryachev-Chaplygin-Sretenskii Case

574

(2)

Clebsch Case

576

(3)

Steklov Case

579

(1)

Liouville Classification of Systems in the Euler Case

580

(10)

Liouville Classification of Systems in the Lagrange Case

590

(8)

Liouville Classification of Systems in the Kovalevskaya Case

598

(10)

Liouville Classification of Systems in the Goryachev-Chaplygin-Stretenskii Case

608

(6)

Liouville Classification of Systems in the Zhukovskii Case

614

(8)

Rough Liouville Classification of Systems in the Clebsch Case

622

(5)

Rough Liouville Classification of Systems in the Steklov Case

627

(4)

Rough Liouville Classification of Integrable Four-Dimensional Rigid Body Systems

631

(13)

The Complete List of Molecules Appearing in Integrable Cases of Rigid Body Dynamics

644

(3)

Maupertuis Principle and Geodesic Equivalence

647

(40)

General Maupertuis Principle

647

(5)

Maupertuis Principle in Rigid Body Dynamics

652

(4)

Classical Cases of Integrability in Rigid Body Dynamics and Related Integrable Geodesic Flows on the Sphere

656

(7)

Euler Case and the Poisson Sphere

657

(1)

Lagrange Case and Metrics of Revolution

658

(1)

Clebsch Case and Geodesic Flow on the Ellipsoid

658

(2)

Goryachev-Chaplygin Case and the Corresponding Integrable Geodesic Flow on the Sphere

660

(1)

Kovalevskaya Case and the Corresponding Integrable Geodesic Flow on the Sphere

661

(2)

Conjecture on Geodesic Flows with Integrals of High Degree

663

(6)

Dini Theorem and the Geodesic Equivalence of Riemannian Metrics

669

(8)

Generalized Dini--Maupertuis Principle

677

(2)

Orbital Equivalence of the Neumann Problem and the Jacobi Problem

679

(2)

Explicit Forms of Some Remarkable Hamiltonians and Their Integrals in Separating Variables

681

(6)

Euler Case in Rigid Body Dynamics and Jacobi Problem about Geodesics on the Ellipsoid. Orbital Isomorphism

687

(18)

Introduction

687

(1)

Jacobi Problem and Euler Case

688

(2)

Liouville Foliations

690

(2)

Rotation Functions

692

(5)

The Main Theorem

697

(1)

Smooth Invariants

698

(3)

Topological Non-conjugacy of the Jacobi Problem and the Euler Case

701

(4)

References

705

(20)

Subject Index

725

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Integrable Hamiltonian Systems: Geometry, Topology, Classification

Summary

Author Biography

Table of Contents

Supplemental Materials

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Integrable Hamiltonian Systems: Geometry, Topology, Classification

Summary

Author Biography

Table of Contents

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