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Rich in applications, this text can be used for a semester-long course in differential equations or mathematical biology or serve as a companion text for a 2-semester sequence beginning with discrete time systems, through a wide array of topics in differential equations, culminating in systems, SIR models, & other applications.
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Rich in applications, this text can be used for a semester-long course in differential equations or mathematical biology or serve as a companion text for a 2-semester sequence beginning with discrete time systems, through a wide array of topics in differential equations, culminating in systems, SIR models, & other applications.
Dieser Download kann aus rechtlichen Gründen nur mit Rechnungsadresse in A, B, BG, CY, CZ, D, DK, EW, E, FIN, F, GR, HR, H, IRL, I, LT, L, LR, M, NL, PL, P, R, S, SLO, SK ausgeliefert werden.
Produktdetails
- Produktdetails
- Verlag: Taylor & Francis
- Seitenzahl: 378
- Erscheinungstermin: 9. August 2024
- Englisch
- ISBN-13: 9781040098073
- Artikelnr.: 72245005
- Verlag: Taylor & Francis
- Seitenzahl: 378
- Erscheinungstermin: 9. August 2024
- Englisch
- ISBN-13: 9781040098073
- Artikelnr.: 72245005
- Herstellerkennzeichnung Die Herstellerinformationen sind derzeit nicht verfügbar.
Christina Alvey is an associate professor of mathematics at Mount Saint Mary College in Newburgh, NY. She earned a PhD in mathematics from Purdue University. Her current research investigates mathematical models in biology and epidemiology, as well as current trends and developments in the field of mathematics education.
Daniel Alvey is a data scientist at Accenture Federal Services. Prior to this, he was an assistant professor of mathematics at Manhattan College in the Bronx, NY, and a visiting assistant professor of mathematics at Trinity College in Hartford, CT. He earned his PhD in mathematics from Wesleyan University, where his research focused on homogeneous dynamics and metric number theory.
Daniel Alvey is a data scientist at Accenture Federal Services. Prior to this, he was an assistant professor of mathematics at Manhattan College in the Bronx, NY, and a visiting assistant professor of mathematics at Trinity College in Hartford, CT. He earned his PhD in mathematics from Wesleyan University, where his research focused on homogeneous dynamics and metric number theory.
1 Modeling with Discrete Equations
1.1 Introduction to Difference Equations
1.1.1 Exponential, Linear Difference, and Logistic Models
1.1.2 Fishery Models
1.2 First Order Difference Equations and Fixed Points
1.2.1 Cobweb Analysis
1.2.2 Fixed Points and Stability
1.3 Solutions of Linear First Order Difference Equations
1.4 Solutions of Linear Homogeneous Second Order Difference Equations
1.4.1 Distinct Roots
1.4.2 Repeated Roots
1.4.3 Complex Roots
1.5 Systems of Difference Equations: Fixed Points and Stability
1.5.1 The Eigenvalue Approach
1.5.2 The Jury Condition
1.5.3 Discrete Interacting Species Models
1.6 Age-Structured Leslie Matrix Models
2 Introduction to Ordinary Differential Equations
2.1 Classification of ODEs and the Verification of their Solutions
2.2 Existence and Uniqueness of Solutions of Linear First Order ODEs
2.3 Vector Fields
3 Modeling with First Order ODEs
3.1 First Order ODEs and their Applications
3.1.1 Exponential, Migration, and Logistic Models
3.1.2 Newton's Law of Cooling
3.1.3 Mixing Models
3.1.4 Interacting Species
3.2 Autonomous Equations
3.3 Bifurcation Diagrams
3.4 Separable Equations
3.5 Integrating Factors
3.6 Exact Equations
4 Modeling with Second Order ODEs
4.1 The Wronskian and the Fundamental Set
4.2 The Characteristic Equation and Solutions of Linear Homogeneous Second
Order ODEs
4.2.1 Distinct Real Roots
4.2.2 Repeated Roots
4.2.3 Complex Roots
4.3 Mechanical and Electrical Vibrations
4.3.1 Mechanical Vibrations: Unforced Springs
4.3.2 Electrical Vibrations: RLC Circuits
4.4 Reduction of Order
4.5 Linear Nonhomogeneous Second Order ODEs: Undetermined Coefficients
4.6 Linear Nonhomogeneous Second Order ODEs: Variation of Parameters
4.7 Forced Vibrations
5 Modeling with Systems of ODEs
5.1 Systems of ODEs and their Applications
5.1.1 Interacting Species
5.1.2 Parallel RLC Circuits
5.1.3 Multiple Tank Mixing Problems
5.2 Stability of Equilibria of Linear Systems using Eigenvalues
5.3 Solutions of Systems of Linear ODEs
5.3.1 Distinct Eigenvalues
5.3.2 Repeated Eigenvalues
5.3.3 Complex Eigenvalues
5.3.4 Solutions of Linear Modeling Problems
5.4 Solutions of Linear Nonhomogeneous Systems: Undetermined Coefficients
5.5 The Stability Criteria for Linear and Nonlinear ODEs
5.6 Phase Planes and Nullclines
6 SIR-Type Models
6.1 The Basic SIR Model with Birth and Death
6.1.1 Equilibria and Stability
6.1.2 The Basic Reproduction Number, R0
6.2 The SEIR Model
6.3 A Model with Vaccination
6.4 Sensitivity Analysis
1.1 Introduction to Difference Equations
1.1.1 Exponential, Linear Difference, and Logistic Models
1.1.2 Fishery Models
1.2 First Order Difference Equations and Fixed Points
1.2.1 Cobweb Analysis
1.2.2 Fixed Points and Stability
1.3 Solutions of Linear First Order Difference Equations
1.4 Solutions of Linear Homogeneous Second Order Difference Equations
1.4.1 Distinct Roots
1.4.2 Repeated Roots
1.4.3 Complex Roots
1.5 Systems of Difference Equations: Fixed Points and Stability
1.5.1 The Eigenvalue Approach
1.5.2 The Jury Condition
1.5.3 Discrete Interacting Species Models
1.6 Age-Structured Leslie Matrix Models
2 Introduction to Ordinary Differential Equations
2.1 Classification of ODEs and the Verification of their Solutions
2.2 Existence and Uniqueness of Solutions of Linear First Order ODEs
2.3 Vector Fields
3 Modeling with First Order ODEs
3.1 First Order ODEs and their Applications
3.1.1 Exponential, Migration, and Logistic Models
3.1.2 Newton's Law of Cooling
3.1.3 Mixing Models
3.1.4 Interacting Species
3.2 Autonomous Equations
3.3 Bifurcation Diagrams
3.4 Separable Equations
3.5 Integrating Factors
3.6 Exact Equations
4 Modeling with Second Order ODEs
4.1 The Wronskian and the Fundamental Set
4.2 The Characteristic Equation and Solutions of Linear Homogeneous Second
Order ODEs
4.2.1 Distinct Real Roots
4.2.2 Repeated Roots
4.2.3 Complex Roots
4.3 Mechanical and Electrical Vibrations
4.3.1 Mechanical Vibrations: Unforced Springs
4.3.2 Electrical Vibrations: RLC Circuits
4.4 Reduction of Order
4.5 Linear Nonhomogeneous Second Order ODEs: Undetermined Coefficients
4.6 Linear Nonhomogeneous Second Order ODEs: Variation of Parameters
4.7 Forced Vibrations
5 Modeling with Systems of ODEs
5.1 Systems of ODEs and their Applications
5.1.1 Interacting Species
5.1.2 Parallel RLC Circuits
5.1.3 Multiple Tank Mixing Problems
5.2 Stability of Equilibria of Linear Systems using Eigenvalues
5.3 Solutions of Systems of Linear ODEs
5.3.1 Distinct Eigenvalues
5.3.2 Repeated Eigenvalues
5.3.3 Complex Eigenvalues
5.3.4 Solutions of Linear Modeling Problems
5.4 Solutions of Linear Nonhomogeneous Systems: Undetermined Coefficients
5.5 The Stability Criteria for Linear and Nonlinear ODEs
5.6 Phase Planes and Nullclines
6 SIR-Type Models
6.1 The Basic SIR Model with Birth and Death
6.1.1 Equilibria and Stability
6.1.2 The Basic Reproduction Number, R0
6.2 The SEIR Model
6.3 A Model with Vaccination
6.4 Sensitivity Analysis
1 Modeling with Discrete Equations
1.1 Introduction to Difference Equations
1.1.1 Exponential, Linear Difference, and Logistic Models
1.1.2 Fishery Models
1.2 First Order Difference Equations and Fixed Points
1.2.1 Cobweb Analysis
1.2.2 Fixed Points and Stability
1.3 Solutions of Linear First Order Difference Equations
1.4 Solutions of Linear Homogeneous Second Order Difference Equations
1.4.1 Distinct Roots
1.4.2 Repeated Roots
1.4.3 Complex Roots
1.5 Systems of Difference Equations: Fixed Points and Stability
1.5.1 The Eigenvalue Approach
1.5.2 The Jury Condition
1.5.3 Discrete Interacting Species Models
1.6 Age-Structured Leslie Matrix Models
2 Introduction to Ordinary Differential Equations
2.1 Classification of ODEs and the Verification of their Solutions
2.2 Existence and Uniqueness of Solutions of Linear First Order ODEs
2.3 Vector Fields
3 Modeling with First Order ODEs
3.1 First Order ODEs and their Applications
3.1.1 Exponential, Migration, and Logistic Models
3.1.2 Newton's Law of Cooling
3.1.3 Mixing Models
3.1.4 Interacting Species
3.2 Autonomous Equations
3.3 Bifurcation Diagrams
3.4 Separable Equations
3.5 Integrating Factors
3.6 Exact Equations
4 Modeling with Second Order ODEs
4.1 The Wronskian and the Fundamental Set
4.2 The Characteristic Equation and Solutions of Linear Homogeneous Second
Order ODEs
4.2.1 Distinct Real Roots
4.2.2 Repeated Roots
4.2.3 Complex Roots
4.3 Mechanical and Electrical Vibrations
4.3.1 Mechanical Vibrations: Unforced Springs
4.3.2 Electrical Vibrations: RLC Circuits
4.4 Reduction of Order
4.5 Linear Nonhomogeneous Second Order ODEs: Undetermined Coefficients
4.6 Linear Nonhomogeneous Second Order ODEs: Variation of Parameters
4.7 Forced Vibrations
5 Modeling with Systems of ODEs
5.1 Systems of ODEs and their Applications
5.1.1 Interacting Species
5.1.2 Parallel RLC Circuits
5.1.3 Multiple Tank Mixing Problems
5.2 Stability of Equilibria of Linear Systems using Eigenvalues
5.3 Solutions of Systems of Linear ODEs
5.3.1 Distinct Eigenvalues
5.3.2 Repeated Eigenvalues
5.3.3 Complex Eigenvalues
5.3.4 Solutions of Linear Modeling Problems
5.4 Solutions of Linear Nonhomogeneous Systems: Undetermined Coefficients
5.5 The Stability Criteria for Linear and Nonlinear ODEs
5.6 Phase Planes and Nullclines
6 SIR-Type Models
6.1 The Basic SIR Model with Birth and Death
6.1.1 Equilibria and Stability
6.1.2 The Basic Reproduction Number, R0
6.2 The SEIR Model
6.3 A Model with Vaccination
6.4 Sensitivity Analysis
1.1 Introduction to Difference Equations
1.1.1 Exponential, Linear Difference, and Logistic Models
1.1.2 Fishery Models
1.2 First Order Difference Equations and Fixed Points
1.2.1 Cobweb Analysis
1.2.2 Fixed Points and Stability
1.3 Solutions of Linear First Order Difference Equations
1.4 Solutions of Linear Homogeneous Second Order Difference Equations
1.4.1 Distinct Roots
1.4.2 Repeated Roots
1.4.3 Complex Roots
1.5 Systems of Difference Equations: Fixed Points and Stability
1.5.1 The Eigenvalue Approach
1.5.2 The Jury Condition
1.5.3 Discrete Interacting Species Models
1.6 Age-Structured Leslie Matrix Models
2 Introduction to Ordinary Differential Equations
2.1 Classification of ODEs and the Verification of their Solutions
2.2 Existence and Uniqueness of Solutions of Linear First Order ODEs
2.3 Vector Fields
3 Modeling with First Order ODEs
3.1 First Order ODEs and their Applications
3.1.1 Exponential, Migration, and Logistic Models
3.1.2 Newton's Law of Cooling
3.1.3 Mixing Models
3.1.4 Interacting Species
3.2 Autonomous Equations
3.3 Bifurcation Diagrams
3.4 Separable Equations
3.5 Integrating Factors
3.6 Exact Equations
4 Modeling with Second Order ODEs
4.1 The Wronskian and the Fundamental Set
4.2 The Characteristic Equation and Solutions of Linear Homogeneous Second
Order ODEs
4.2.1 Distinct Real Roots
4.2.2 Repeated Roots
4.2.3 Complex Roots
4.3 Mechanical and Electrical Vibrations
4.3.1 Mechanical Vibrations: Unforced Springs
4.3.2 Electrical Vibrations: RLC Circuits
4.4 Reduction of Order
4.5 Linear Nonhomogeneous Second Order ODEs: Undetermined Coefficients
4.6 Linear Nonhomogeneous Second Order ODEs: Variation of Parameters
4.7 Forced Vibrations
5 Modeling with Systems of ODEs
5.1 Systems of ODEs and their Applications
5.1.1 Interacting Species
5.1.2 Parallel RLC Circuits
5.1.3 Multiple Tank Mixing Problems
5.2 Stability of Equilibria of Linear Systems using Eigenvalues
5.3 Solutions of Systems of Linear ODEs
5.3.1 Distinct Eigenvalues
5.3.2 Repeated Eigenvalues
5.3.3 Complex Eigenvalues
5.3.4 Solutions of Linear Modeling Problems
5.4 Solutions of Linear Nonhomogeneous Systems: Undetermined Coefficients
5.5 The Stability Criteria for Linear and Nonlinear ODEs
5.6 Phase Planes and Nullclines
6 SIR-Type Models
6.1 The Basic SIR Model with Birth and Death
6.1.1 Equilibria and Stability
6.1.2 The Basic Reproduction Number, R0
6.2 The SEIR Model
6.3 A Model with Vaccination
6.4 Sensitivity Analysis