Delay Ordinary and Partial Differential Equations (Advances in Applied Mathematics)

Cover
Half Title
Series Page
Title Page
Copyright Page
Contents
Preface
Notations and Remarks
Authors
1. Delay Ordinary Differential Equations
1.1. First-Order Equations. Cauchy Problem. Method of Steps. Exact Solutions
1.1.1. Preliminary Remarks
1.1.2. First-Order ODEs with Constant Delay. Cauchy Problem. Qualitative Features
1.1.3. Exact Solutions to a First-Order Linear ODE with Constant Delay. The Lambert W Function and Its Properties
1.1.4. First-Order Nonlinear ODEs with Constant Delay That Admit Linearization or Exact Solutions
1.1.5. Method of Steps. Solution of the Cauchy Problem for a First-Order ODE with Constant Delay
1.1.6. Equations with Variable Delay. ODEs with Proportional Delay
1.1.7. Existence and Uniqueness of Solutions. Suppression of Singularities in Solving Blow-Up Problems
1.2. Second- and Higher-Order Delay ODEs. Systems of Delay ODEs
1.2.1. Basic Concepts. The Cauchy Problem
1.2.2. Second-Order Linear Equations. The Cauchy Problem. Exact Solutions
1.2.3. Higher-Order Linear Delay ODEs
1.2.4. Linear Systems of First- and Second-Order ODEs with Delay. The Cauchy Problem. Exact Solutions
1.3. Stability (Instability) of Solutions to Delay ODEs
1.3.1. Basic Concepts. General Remarks on Stability of Solutions to Linear Delay ODEs
1.3.2. Stability of Solutions to Linear ODEs with a Single Constant Delay
1.3.3. Stability of Solutions to Linear ODEs with Several Constant Delays
1.3.4. Stability Analysis of Solutions to Nonlinear Delay ODEs by the First Approximation
1.4. Exact and Approximate Analytical Solution Methods for Delay ODEs
1.4.1. Using Integral Transforms for Solving Linear Problems
1.4.2. Representation of Solutions as Power Series in the Independent Variable
1.4.3. Method of Regular Expansion in a Small Parameter
1.4.4. Method of Matched Asymptotic Expansions. Singular Perturbation Problems with a Boundary Layer
1.4.5. Method of Successive Approximations and Other Iterative Methods
1.4.6. Galerkin-Type Projection Methods. Collocation Method
2. Linear Partial Differential Equations with Delay
2.1. Properties and Specific Features of Linear Equations and Problems with Constant Delay
2.1.1. Properties of Solutions to Linear Delay Equations
2.1.2. General Properties and Qualitative Features of Delay Problems
2.2. Linear Initial-Boundary Value Problems with Constant Delay
2.2.1. First Initial-Boundary Value Problem for One-Dimensional Parabolic Equations with Constant Delay
2.2.2. Other Problems for a One-Dimensional Parabolic Equation with Constant Delay
2.2.3. Problems for Linear Parabolic Equations with Several Variables and Constant Delay
2.2.4. Problems for Linear Hyperbolic Equations with Constant Delay
2.2.5. Stability and Instability Conditions for Solutions to Linear Initial-Boundary Value Problems
2.3. Hyperbolic and Differential-Difference Heat Equations
2.3.1. Derivation of the Hyperbolic and Differential-Difference Heat Equations
2.3.2. Stokes Problem and Initial-Boundary Value Problems for the Differential-Difference Heat Equation
2.4. Linear Initial-Boundary Value Problems with Proportional Delay
2.4.1. Preliminary Remarks
2.4.2. First Initial-Boundary Value Problem for a Parabolic Equation with Proportional Delay
2.4.3. Other Initial-Boundary Value Problems for a Parabolic Equation with Proportional Delay
2.4.4. Initial-Boundary Value Problem for a Linear Hyperbolic Equation with Proportional Delay
3. AnalyticalMethods and Exact Solutions to Delay PDEs. Part I
3.1. Remarks and Definitions. Traveling Wave Solutions
3.1.1. Preliminary Remarks. Terminology. Classes of Equations Concerned
3.1.2. States of Equilibrium. Traveling Wave Solutions. Exact Solutions in Closed Form
3.1.3. Traveling Wave Front Solutions to Nonlinear Reaction-Diffusion Type Equations
3.2. Multiplicative and Additive Separable Solutions
3.2.1. Preliminary Remarks. Terminology. Examples
3.2.2. Delay Reaction-Diffusion Equations Admitting Separable Solutions
3.2.3. Delay Klein–Gordon Type Equations Admitting Separable Solutions
3.2.4. Some Generalizations
3.3. Generalized and Functional Separable Solutions
3.3.1. Generalized Separable Solutions
3.3.2. Functional Separable Solutions
3.3.3. Using Linear Transformations to Construct Generalized and Functional Separable Solutions
3.4. Method of Functional Constraints
3.4.1. General Description of the Method of Functional Constraints
3.4.2. Exact Solutions to Quasilinear Delay Reaction-Diffusion Equations
3.4.3. Exact Solutions to More Complicated Nonlinear Delay Reaction-Diffusion Equations
3.4.4. Exact Solutions to Nonlinear Delay Klein–Gordon Type Wave Equations
4. AnalyticalMethods and Exact Solutions to Delay PDEs. Part II
4.1. Methods for Constructing Exact Solutions to Nonlinear Delay PDEs Using Solutions to Simpler Non-Delay PDEs
4.1.1. The First Method for Constructing Exact Solutions to Delay PDEs. General Description and Simple Examples
4.1.2. Using the First Method for Constructing Exact Solutions to Nonlinear Delay PDEs
4.1.3. The Second Method for Constructing Exact Solutions to Delay PDEs. General Description and Simple Examples
4.1.4. Employing the Second Method to Construct Exact Solutions to Nonlinear Delay PDEs
4.2. Systems of Nonlinear Delay PDEs. Generating Equations Method
4.2.1. General Description of the Method and Application Examples
4.2.2. Quasilinear Systems of Delay Reaction-Diffusion Equations and Their Exact Solutions
4.2.3. Nonlinear Systems of Delay Reaction-Diffusion Equations and Their Exact Solutions
4.2.4. Some Generalizations
4.3. Reductions and Exact Solutions of Lotka–Volterra Type Systems and More Complex Systems of PDEs with Several Delays
4.3.1. Reaction-Diffusion Systems with Several Delays. The Lotka– Volterra System
4.3.2. Reductions and Exact Solutions of Systems of PDEs with Different Diffusion Coefficients (a1 ≠ a2)
4.3.3. Reductions and Exact Solutions of Systems of PDEs with Equal Diffusion Coefficients (a1 = a2)
4.3.4. Systems of Delay PDEs Homogeneous in the Unknown Functions
4.4. Nonlinear PDEs with Proportional Arguments. Principle of Analogy of Solutions
4.4.1. Principle of Analogy of Solutions
4.4.2. Exact Solutions to Quasilinear Diffusion Equations with Proportional Delay
4.4.3. Exact Solutions to More Complicated Nonlinear Diffusion Equations with Proportional Delay
4.4.4. Exact Solutions to Nonlinear Wave-Type Equations with Proportional Delay
4.5. Unstable Solutions and Hadamard Ill-Posedness of Some Delay Problems
4.5.1. Solution Instability for One Class of Nonlinear PDEs with Constant Delay
4.5.2. Hadamard Ill-Posedness of Some Delay Problems
5. Numerical Methods for Solving Delay Differential Equations
5.1. Numerical Integration of Delay ODEs
5.1.1. Main Concepts and Definitions
5.1.2. Qualitative Features of the Numerical Integration of Delay ODEs
5.1.3. Modified Method of Steps
5.1.4. Numerical Methods for ODEs with Constant Delay
5.1.5. Numerical Methods for ODEs with Proportional Delay. Cauchy Problem
5.1.6. Shooting Method (Boundary Value Problems)
5.1.7. Integration of Stiff Systems of Delay ODEs Using the Mathematica Software
5.1.8. Test Problems for Delay ODEs. Comparison of Numerical and Exact Solutions
5.2. Numerical Integration of Delay PDEs
5.2.1. Preliminary Remarks. Method of Time-Domain Decomposition
5.2.2. Method of Lines—Reduction of a Delay PDE to a System of Delay ODEs
5.2.3. Finite Difference Methods
5.3. Construction, Selection, and Usage of Test Problems for Delay PDEs
5.3.1. Preliminary Remarks
5.3.2. Main Principles for Selecting Test Problems
5.3.3. Constructing Test Problems
5.3.4. Comparison of Numerical and Exact Solutions to Nonlinear Delay Reaction-Diffusion Equations
5.3.5. Comparison of Numerical and Exact Solutions to Nonlinear Delay Klein–Gordon Type Wave Equations
6. Models and Delay Differential Equations Used in Applications
6.1. Models Described by Nonlinear Delay ODEs
6.1.1. Hutchinson’s Equation—a Delay Logistic Equation
6.1.2. Nicholson’s Equation
6.1.3. Mackey–Glass Hematopoiesis Model
6.1.4. Other Nonlinear Models with Delay
6.2. Models of Economics and Finance Described by ODEs
6.2.1. The Simplest Model of Macrodynamics of Business Cycles
6.2.2. Model of Interaction of Three Economical Parameters
6.2.3. Delay Model Describing Tax Collection in a Closed Economy
6.3. Models and Delay PDEs in Population Theory
6.3.1. Preliminary Remarks
6.3.2. Diffusive Logistic Equation with Delay
6.3.3. Delay Diffusion Equation Taking into Account Nutrient Limitation
6.3.4. Lotka–Volterra Type Diffusive Logistic Model with Several Delays
6.3.5. Nicholson’s Reaction-Diffusion Model with Delay
6.3.6. Model That Takes into Account the Effect of Plant Defenses on a Herbivore Population
6.4. Models and Delay PDEs Describing the Spread of Epidemics and Development of Diseases
6.4.1. Classical SIR Model of Epidemic Spread
6.4.2. Two-Component Epidemic SI Model
6.4.3. Epidemic Model of the New Coronavirus Infection
6.4.4. Hepatitis B Model
6.4.5. Model of Interaction between Immunity and Tumor Cells
6.5. Other Models Described by Nonlinear Delay PDEs
6.5.1. Belousov–Zhabotinsky Oscillating Reaction Model
6.5.2. Mackey–Glass Model of Hematopoiesis
6.5.3. Model of Heat Treatment of Metal Strips
6.5.4. Food Chain Model
6.5.5. Models of Artificial Neural Networks
References
Index