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Differential Equations James R. Brannan

Differential Equations By James R. Brannan

Differential Equations by James R. Brannan

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Summary

Written by one of the most well known names in mathematics, this book provides readers with a more modern approach to differential equations. It is streamlined for easier readability while incorporating the latest topics and technologies.

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Differential Equations Summary

Differential Equations: An Introduction to Modern Methods and Applications by James R. Brannan

Differential Equations: An Introduction to Modern Methods and Applications is a textbook designed for a first course in differential equations commonly taken by undergraduates majoring in engineering or science. It emphasizes a systems approach to the subject and integrates the use of modern computing technology in the context of contemporary applications from engineering and science. Section exercises throughout the text are designed to give students hands--on experience in modeling, analysis, and computer experimentation. Optional projects at the end of each chapter provide additional opportunitites for students to explore the role played by differential equations in scientific and engineering problems of a more serious nature.

About James R. Brannan

William E. Boyce received his B.A. degree in Mathematics from Rhodes College, and his M.S. and Ph.D. degrees in Mathematics from Carnegie--Mellon University. He is a member of the American Mathematical Society, the Mathematical Association of America, and the Society for Industrial and Applied Mathematics. He is currently the Edward P. Hamilton Distinguished Professor Emeritus of Science Education (Department of Mathematical Sciences) at Rensselaer. He is the author of numerous technical papers in boundary value problems and random differential equations and their applications. He is the author of several textbooks including two differential equations texts, and is the coauthor (with M.H. Holmes, J.G. Ecker, andW.L. Siegmann) of a text on using Maple to explore Calculus. He is also coauthor (with R.L. Borrelli and C.S. Coleman) of Differential Equations LaboratoryWorkbook (Wiley 1992), which received the EDUCOMBest Mathematics Curricular InnovationAward in 1993. Professor Boyce was a member of the NSF--sponsored CODEE (Consortium for Ordinary Differential Equations Experiments) that led to the widely--acclaimed ODE Architect. He has also been active in curriculum innovation and reform. Among other things, he was the initiator of the Computers in Calculus project at Rensselaer, partially supported by the NSF. In 1991 he received the William H.Wiley Distinguished FacultyAward given by Rensselaer.

Table of Contents

1. Introduction. 1.1 Some Basic Mathematical Models; Direction Fields. 1.2 Solutions of Some Differential Equations. 1.3 Numerical Approximations: Eulera s Method. 1.4 Classification of Differential Equations. 2. First Order Differential Equations. 2.1 Linear Equations; Method of Integrating Factors. 2.2 Separable Equations. 2.3 Modeling with First Order Equations. 2.4 Differences Between Linear and Nonlinear Equations. 2.5 Autonomous Equations and Population Dynamics. 2.6 Exact Equations and Integrating Factors. 2.7 Accuracy of Numerical Methods. 2.8 Improved Euler and Runge Kutta Methods. Summary. Projects. 2.P.1 Harvesting a Renewable Resource. 2.P.2 Designing a Drip Dispenser for a Hydrology Experiment. 2.P.3 A Mathematical Model of a Groundwater Contaminant Source. 2.P.4 Monte Carlo Option Pricing: Pricing Financial Options by Flipping a Coin. 3. Systems of Two First Order Equations. 3.1 Systems of Two Linear Algebraic Equations. 3.2 Systems of Two First Order Linear Differential Equations. 3.3 Homogeneous Linear Systems with Constant Coefficients. 3.4 Complex Eigenvalues. 3.5 Repeated Eigenvalues. 3.6 A Brief Introduction to Nonlinear Systems. 3.7 Numerical Methods for Systems of First Order Equations. Summary. Projects. 3.P.1 Eigenvalue Placement Design of a Satellite Attitude Control System. 3.P.2 Estimating Rate Constants for an Open Two Compartment Model. 3.P.3 The Ray Theory of Wave Propagation. 3.P.4 A Blood Brain Pharmacokinetic Model. 4. Second Order Linear Equations. 4.1 Definitions and Examples. 4.2 Theory of Second Order Linear Homogeneous Equations. 4.3 Linear Homogeneous Equations with Constant Coefficients. 4.4 Characteristic Equations with Complex Roots. 4.5 Mechanical and Electrical Vibrations. 4.6 Nonhomogeneous Equations; Method of Undetermined Coefficients. 4.7 Forced Vibrations, Frequency Response, and Resonance. 4.8 Variation of Parameters. Summary. Projects. 4.P.1 A Vibration Insulation Problem. 4.P.2 Linearization of a Nonlinear Mechanical System. 4.P.3 A Spring Mass Event Problem. 4.P.4 Uniformly Distributing Points on a Sphere. 4.P.5 Euler Lagrange Equations. 5. The Laplace Transform. 5.1 Definition of the Laplace Transform. 5.2 Properties of the Laplace Transform. 5.3 The Inverse Laplace Transform. 5.4 Solving Differential Equations with Laplace Transforms. 5.5 Discontinuous Functions and Periodic Functions. 5.6 Differential Equations with Discontinuous Forcing Functions. 5.7 Impulse Functions. 5.8 Convolution Integrals and Their Applications. 5.9 Linear Systems and Feedback Control. Summary. Projects. 5.P.1 An Electric Circuit Problem. 5.P.2 Effects of Pole Locations on Step Responses of Second Order Systems. 5.P.3 The Watt Governor, Feedback Control, and Stability. 6. Systems of First Order Linear Equations. 6.1 Definitions and Examples. 6.2 Basic Theory of First Order Linear Systems. 6.3 Homogeneous Linear Systems with Constant Coefficients. 6.4 Complex Eigenvalues. 6.5 Fundamental Matrices and the Exponential of a Matrix. 6.6 Nonhomogeneous Linear Systems. 6.7 Defective Matrices. Summary. Projects. 6.P.1 A Compartment Model of Heat Flow in a Rod. 6.P.2 Earthquakes and Tall Buildings. 6.P.3 Controlling a Spring Mass System to Equilibrium. 7. Nonlinear Differential Equations and Stability. 7.1 Autonomous Systems and Stability. 7.2 Almost Linear Systems. 7.3 Competing Species. 7.4 Predator Prey Equations. 7.5 Periodic Solutions and Limit Cycles. 7.6 Chaos and Strange Attractors: The Lorenz Equations. Summary. Projects. 7.P.1 Modeling of Epidemics. 7.P.2 Harvesting in a Competitive Environment. 7.P.3 The Rossler System. Appendix A: Matrix Algebra. A.1 Matrices. A.2 Systems of Linear Algebraic Equations, Linear Independence, and Rank. A.3 Determinants and Inverses. A.4 The Eigenvalue Problem. Appendix B: Complex Variables. Answers to Selected Problems. Index.

Additional information

CIN0471651419G
9780471651413
0471651419
Differential Equations: An Introduction to Modern Methods and Applications by James R. Brannan
James R. Brannan
Used - Good
Hardback
John Wiley and Sons Ltd
20061101
704
N/A
Book picture is for illustrative purposes only, actual binding, cover or edition may vary.
This is a used book - there is no escaping the fact it has been read by someone else and it will show signs of wear and previous use. Overall we expect it to be in good condition, but if you are not entirely satisfied please get in touch with us

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