《动力系统Ⅴ:分歧理论和突变理论》是2009年科学出版社出版的图书,作者是阿诺德。
《国外数学名著系列均(续1)(影印版)50:动力系统4(分歧理论和突变理论)》主要内容:Both bifurca来自tion theory and c了钱随皇误所判排服掌露atastrophe theory are studies of smooth systems,tbcusing on properti360百科es that seem manifestly non-smooth. Bifurcations are sudden changes that occur in a system 汽投季与as one or mor演你待杀从皇助真办e paramete克哥历神无深易加rs are varied.Catastrophe theory is accurately described as singularity theory an部板议个光顾复越所宣d its applications.
These two theories a你众盾re important 况煤买tools in the 参晚搞意精商study of differential e够协等quations and o序黑级f related physical systems.Analyzing the bifurcations or singularities of a system provides useful qualitative information about its behaviour. The authors have written this book with reffeshing clarity.Theexposition is masterful,with penetrating insights.
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Chapter 1. Bifurcations of Equilibria
1. Families and Deformations
1.1. Families of Vector Fields
1.2. The Space of Jet制设气建s
1.3. Sard's Lemma and Transversality Theorems
1.4. Simplest Applications: Singular Points of Generic Vector Fields
1.5. Topologically Versal Deformations
1.6. The Reduc黑书迅板承广载tion Theorem
1.7. Generic and Principal Families
2. Bifurcations of Singular Points in Generic O要但打境胞承破千走内买ne-Parameter Famil湖京元参温便唱盐仍垂德ies
2.1 Typical Germs and Principal Families
2.2. Soft and Hard Loss of Stability
3. Bifurcations of Singular Points in Generic Multi-Parameter Families with Simply Degenerate Linear Parts
3.1. Principal Families
3.2. Bifurcation Diagrams of the Principal Families (3-+) i掉素唱式附位就探向德n Table 1
3.3. Bifurcation Diagram决s with Respect to Weak Equivalence and Phase Portraits of the Principal Families (4-+) in Table 1
4. Bifurcations of Singular Points of Vector Fields with a Doubly-Degenerate Linear Part
4.1. A List of Degeneracies
4.2. Two Zero Eigenvalues
4.3. Reductions to Two-Dimensional Systems
4.4. One Zero and a Pair of Purely Imaginary Eigenvalues
4.5. Two Purely Imaginary Pairs
4.6. Principal Deformations of Equations of Difficult Type in Problems with Two Pairs of Purely Imaginary Eigenvalues (Following Zolitdek)
5. The Exponents of Soft and Hard Loss of Stability
5.1. Definitions
5.2. Table of Exponents
Chapter 2. Bifurcations of Limit Cycles
1. Bifurcations of Limit Cycles in Generic One-Parameter Families
1.1. Multiplier I
1.2. Multiplier-1 and Period-Doubling Bifurcations
1.3. A Pair of Complex Conjugate Multipliers
1.4. Nonlocal Bifurcations in One-Parameter Families of Diffeomorphisms
1.5. Nonlocal Bifurcations of Periodic Solutions
1.6. Bifurcations Resulting in Destructions of Invariant Tori
2. Bifurcations of Cycles in Generic Two-Parameter Families with an
Additional Simple Degeneracy
2.1. A List of Degeneracies
2.2. A Multiplier+1or-1 with Additional Degeneracy in the Nonlinear Terms
2.3. A Pair of Multipliers on the Unit Circle with Additional Degeneracy in the Nonlinear Terms
3. Bifurcations of Cycles in Generic Two-Parameter Families with Strong Resonances of Orders q≠4
3.1. The Normal Form in the Case of Unipotent Jordan Blocks
3.2. Averaging in the Seifert and the M6bius Foliations
3.3. Principal Vector Fields and their Deformations
3.4. Versality of Principal Deformations
3.5. Bifurcations of Stationary Solutions of Periodic Differential Equations with Strong Resonances of Orders q≠4
4. Bifurcations of Limit Cycles for a Pair of Multipliers Crossing the
Unit Circle at±i
4.1. Degenerate Families
4.2. Degenerate Families Found Analytically
4.3. Degenerate Families Found Numerically
4.4. Bifurcations in Nondegenerate Families
4.5. Limit Cycles of Systems with a Fourth Order Symmetry
5. Finitely-Smooth Normal Forms of Local Families
5.1. A Synopsis of Results
5.2. Definitions and Examples
5.3. General Theorems and Deformations of Nonresonant Germs
5.4. Reduction to Linear Normal Form
5.5. Deformations of Germs of Diffeomorphisms of Poincare Type
5.6. Deformations of Simply Resonant Hyperbolic Germs
5.7. Deformations of Germs of Vector Fields with One Zero Eigenvalue at a Singular Point
5.8. Functional Invariants of Diffeomorphisms of the Line
5.9. Functional Invariants of Local Families of Diffeomorphisms
5.10. Functional Invariants of Families of Vector Fields
5.11. Functional Invariants of Topological Classifications of Local Families of Diffeomorphisms of the Line
6. Feigenbaum Universality for Diffeomorphisms and Flows
6.1. Period-Doubling Cascades
6.2. Perestroikas of Fixed Points
6.3. Cascades of n-fold Increases of Period
6.4. Doubling in Hamiltonian Systems
6.5. The Period-Doubling Operator for One-Dimensional Mappings
6.6. The Universal Period-Doubling Mechanism for Diffeomorphisms
Chapter 3. Nonlocal Bifurcations
1. Degeneracies of Codimension 1. Summary of Results
1.1. Local and Nonlocal Bifurcations
1.2. Nonhyperbolic Singular Points
1.3. Nonhyperbolic Cycles
1.4. Nontransversal Intersections of Manifolds
1.5. Contours
1.6. Bifurcation Surfaces
1.7. Characteristics of Bifurcations
1.8. Summary of Results
2. Nonlocal Bifurcations of Flows on Two-Dimensional Surfaces
2.1. Semilocal Bifurcations of Flows on Surfaces
2.2. Nonlocal Bifurcations on a Sphere: The One-Parameter Case .
2.3. Generic Families of Vector Fields
2.4. Conditions for Genericity
2.5. One-Parameter Families on Surfaces different from the Sphere
2.6. Global Bifurcations of Systems with a Global Transversal Section on a Torus
2.7. Some Global Bifurcations on a Klein bottle
2.8. Bifurcations on a Two-Dimensional Sphere: The Multi-Parameter Case
2.9. Some Open Questions
3. Bifurcations of Trajectories Homoclinic to a Nonhyperbolic Singular Point
3.1. A Node in its Hyperbolic Variables
3.2. A Saddle in its Hyperbolic Variables: One Homoclinic Trajectory
3.3. The Topological Bernoulli Automorphism
3.4. A Saddle in its Hyperbolic Variables: Several Homoclinic Trajectories
3.5. Principal Families
4. Bifurcations of Trajectories Homoclinic to a Nonhyperbolic Cycle
4.1. The Structure of a Family of Homoclinic Trajectories
4.2. Critical and Noncritical Cycles
4.3. Creation of a Smooth Two-Dimensional Attractor
4.4. Creation of Complex Invariant Sets (The Noncritical Case) ...
4.5. The Critical Case
4.6. A Two-Step Transition from Stability to Turbulence
4.7. A Noncompact Set of Homoclinic Trajectories
4.8. Intermittency
4.9. Accessibility and Nonaccessibility
4.10. Stability of Families of Diffeomorphisms
4.11. Some Open Questions
5. Hyperbolic Singular Points with Homoclinic Trajectories
5.1. Preliminary Notions: Leading Directions and Saddle Numbers
5.2. Bifurcations of Homoclinic Trajectories of a Saddle that Take Place on the Boundary of the Set of Morse-Smale Systems
5.3. Requirements for Genericity
5,4, Principal Families in R3 and their Properties
5.5. Versality of the Principal Families
5.6. A Saddle with Complex Leading Direction in R3
5.7. An Addition: Bifurcations of Homoclinic Loops Outside the Boundary of a Set of Morse-Smale Systems
5.8. An Addition: Creation of a Strange Attractor upon Bifurcation of a Trajectory Homoclinic to a Saddle
6. Bifurcations Related to Nontransversal Intersections
6.1. Vector Fields with No Contours and No Homoclinic Trajectories
6.2. A Theorem on Inaccessibility
6.3. Moduli
6.4. Systems with Contours
6.5. Diffeomorphisms with Nontrivial Basic Sets
6.6, Vector Fields in R3 with Trajectories Homoclinic to a Cycle
6.7. Symbolic Dynamics
6.8. Bifurcations of Smale Horseshoes
6.9. Vector Fields on a Bifurcation Surface
6.10. Diffeomorphisms with an Infinite Set of Stable Periodic Trajectories
7. Infinite Nonwandering Sets
7.1. Vector Fields on the Two-Dimensional Torus
7.2. Bifurcations of Systems with Two Homoclinic Curves of a Saddle
7.3. Systems with Feigenbaum Attractors
7.4. Birth of Nonwandering Sets
7.5. Persistence and Smoothness of Invariant Manifolds
7.6. The Degenerate Family and Its Neighborhood in Function Space
7.7. Birth of Tori in a Three-Dimensional Phase Space
8. Attractors and their Bifurcations
8.1. The Likely Limit Set According to Milnor (1985)
8.2. Statistical Limit Sets
8.3. Internal Bifurcations and Crises of Attractors
8.4. Internal Bifurcations and Crises of Equilibria and Cycles
8.5. Bifurcations of the Two-Dimensional Torus
Chapter 4. Relaxation Oscillations
1. Fundamental Concepts
1.1. An Example: van der Pors Equation
1.2. Fast and Slow Motions
1.3. The Slow Surface and Slow Equations
1.4. The Slow Motion as an Approximation to the Perturbed Motion
1.5. The Phenomenon of Jumping
2. Singularities of the Fast and Slow Motions
2.1. Singularities of Fast Motions at Jump Points of Systems with One Fast Variable
2.2. Singularities of Projections of the Slow Surface
2.3. The Slow Motion for Systems with One Slow Variable
2.4. The Slow Motion for Systems with Two Slow Variables
2.5. Normal Forms of Phase Curves of the Slow Motion
2.6. Connection with the Theory of Implicit Differential Equations
2.7. Degeneration of the Contact Structure
3. The Asymptotics of Relaxation Oscillations
3.1. Degenerate Systems
3.2. Systems of First Approximation
3.3. Normalizations of Fast-Slow Systems with Two Slow Variables for
3.4. Derivation of the Systems of First Approximation
3.5. Investigation of the Systems of First Approximation
3.6. Funnels
3.7. Periodic Relaxation Oscillations in the Plane
4. Delayed Loss of Stability as a Pair of Eigenvalues Cross the Imaginary Axis
4.1. Generic Systems
4.2. Delayed Loss of Stability
4.3. Hard Loss of Stability in Analytic Systems of Type 2
4.4. Hysteresis
4.5. The Mechanism of Delay
4.6. Computation of the Moment of Jumping in Analytic Systems
4.7. Delay Upon Loss of Stability by a Cycle
4.8. Delayed Loss of Stability and "Ducks" .
5. Duck Solutions
5.1. An Example: A Singular Point on the Fold of the Slow Surface
5.2. Existence of Duck Solutions
5.3. The Evolution of Simple Degenerate Ducks
5.4. A Semi-local Phenomenon: Ducks with Relaxation
5.5. Ducks in R3 and Rn
Recommended Literature
References
Additional References
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