Undergraduate Texts in Mathematics Editors S. Axler K.A. Ribet Undergraduate Texts in Mathematics Abbott: Understanding Analysis. Chambert-Loir: A Field Guide to Algebra Anglin: Mathematics: A Concise History Childs: A Concrete Introduction to and Philosophy. Higher Algebra. Second edition. Readings in Mathematics. Chung/AitSahlia: Elementary Probability Anglin/Lambek: The Heritage of Theory: With Stochastic Processes and Thales. an Introduction to Mathematical Readings in Mathematics. Finance. Fourth edition. Apostol: Introduction to Analytic Cox/Little/O'Shea: Ideals, Varieties, Number Theory. Second edition. and Algorithms. Second edition. Armstrong: Basic Topology. Croom: Basic Concepts of Algebraic Armstrong: Groups and Symmetry. Topology. Axler: Linear Algebra Done Right. Curtis: Linear Algebra: An Introductory Second edition. Approach. Fourth edition. Beardon: Limits: A New Approach to Daepp/Gorkin: Reading, Writing, and Real Analysis. Proving: A Closer Look at Bak/Newman: Complex Analysis. Mathematics. Second edition. Devlin: The Joy of Sets: Fundamentals BanchoffAVermer: Linear Algebra of Contemporary Set Theory. Through Geometry. Second edition. Second edition. Berberian: A First Course in Real Dixmier: General Topology. Analysis. Driver: Why Math? Bix: Conies and Cubics: A Ebbinghaus/Flum/Thomas: Concrete Introduction to Algebraic Mathematical Logic. Second edition. Curves. Edgar: Measure, Topology, and Fractal Bremaud: An Introduction to Geometry. Probabilistic Modeling. Elaydi: An Introduction to Difference Bressoud: Factorization and Primality Equations. Third edition. Testing. Erdos/Suranyi: Topics in the Theory of Bressoud: Second Year Calculus. Numbers. Readings in Mathematics. Estep: Practical Analysis in One Variable. Brickman: Mathematical Introduction Exner: An Accompaniment to Higher to Linear Programming and Game Mathematics. Theory. Exner: Inside Calculus. Browder: Mathematical Analysis: Fine/Rosenberger: The Fundamental An Introduction. Theory of Algebra. Buchmann: Introduction to Fischer: Intermediate Real Analysis. Cryptography. Flanigan/Kazdan: Calculus Two: Linear Buskes/van Rooij: Topological Spaces: and Nonlinear Functions. Second From Distance to Neighborhood. edition. Callahan: The Geometry of Spacetime: Fleming: Functions of Several Variables. An Introduction to Special and General Second edition. Relavitity. Foulds: Combinatorial Optimization for Carter/van Brunt: The Lebesgue- Undergraduates. Stieltjes Integral: A Practical Foulds: Optimization Techniques: An Introduction. Introduction. Cederberg: A Course in Modern Franklin: Methods of Mathematical Geometries. Second edition. Economics. (continued after index) J. David Logan A First Course in Differential Equations With 55 Figures J.DavidLogan WillaCatherProfessorofMathematics DepartmentofMathematics UniversityofNebraskaatLincoln Lincoln,NE68588-0130 USA [email protected] EditorialBoard S.Axler K.A.Ribet MathematicsDepartment DepartmentofMathematics SanFranciscoStateUniversity UniversityofCaliforniaatBerkeley SanFrancisco,CA94132 Berkeley,CA94720-3840 USA USA [email protected] [email protected] MathematicsSubjectClassification(2000):34-xx,15-xx LibraryofCongressControlNumber:2005926697(hardcover); LibraryofCongressControlNumber:2005926698(softcover) ISBN-10:0-387-25963-5(hardcover) ISBN-13:978-0387-25963-5 ISBN-10:0-387-25964-3(softcover) ISBN-13:978-0387-25964-2 ©2006SpringerScience+BusinessMedia,Inc. Allrightsreserved.Thisworkmaynotbetranslatedorcopiedinwholeorinpartwithout thewrittenpermissionofthepublisher(SpringerScience+BusinessMedia,Inc.,233Spring Street,NewYork,NY10013,USA),exceptforbriefexcerptsinconnectionwithreviewsor scholarlyanalysis.Useinconnectionwithanyformofinformationstorageandretrieval, electronic adaptation, computer software, or by similar or dissimilar methodology now knownorhereafterdevelopedisforbidden. Theuseinthispublicationoftradenames,trademarks,servicemarks,andsimilarterms, eveniftheyarenotidentifiedassuch,isnottobetakenasanexpressionofopinionas towhetherornottheyaresubjecttoproprietaryrights. PrintedintheUnitedStatesofAmerica. (SBA) 9 8 7 6 5 4 3 2 1 springeronline.com Dedicated to— Reece Charles Logan, Jaren Logan Golightly Contents Preface ......................................................... xi To the Student ................................................. xiii 1. Differential Equations and Models .......................... 1 1.1 Differential Equations..................................... 2 1.1.1 Equations and Solutions............................. 2 1.1.2 Geometrical Interpretation .......................... 9 1.2 Pure Time Equations ..................................... 13 1.3 Mathematical Models ..................................... 19 1.3.1 Particle Dynamics .................................. 21 1.3.2 Autonomous Differential Equations ................... 28 1.3.3 Stability and Bifurcation ............................ 41 1.3.4 Heat Transfer...................................... 45 1.3.5 Chemical Reactors.................................. 48 1.3.6 Electric Circuits.................................... 51 2. Analytic Solutions and Approximations..................... 55 2.1 Separation of Variables.................................... 55 2.2 First-Order Linear Equations .............................. 61 2.3 Approximation........................................... 70 2.3.1 Picard Iteration .................................... 71 2.3.2 Numerical Methods................................. 74 2.3.3 Error Analysis ..................................... 78 viii Contents 3. Second-Order Differential Equations ........................ 83 3.1 Particle Mechanics........................................ 84 3.2 Linear Equations with Constant Coefficients ................. 87 3.3 The Nonhomogeneous Equation ............................ 95 3.3.1 Undetermined Coefficients........................... 96 3.3.2 Resonance.........................................102 3.4 Variable Coefficients ......................................105 3.4.1 Cauchy–Euler Equation .............................106 3.4.2 Power Series Solutions ..............................109 3.4.3 Reduction of Order .................................111 3.4.4 Variation of Parameters .............................112 3.5 Boundary Value Problems and Heat Flow ...................117 3.6 Higher-Order Equations ...................................124 3.7 Summary and Review.....................................127 4. Laplace Transforms.........................................133 4.1 Definition and Basic Properties ............................133 4.2 Initial Value Problems ....................................140 4.3 The Convolution Property.................................145 4.4 Discontinuous Sources.....................................149 4.5 Point Sources ............................................152 4.6 Table of Laplace Transforms ...............................157 5. Linear Systems .............................................159 5.1 Introduction .............................................159 5.2 Matrices ................................................165 5.3 Two-Dimensional Systems .................................179 5.3.1 Solutions and Linear Orbits..........................179 5.3.2 The Eigenvalue Problem ............................185 5.3.3 Real Unequal Eigenvalues ...........................187 5.3.4 Complex Eigenvalues ...............................189 5.3.5 Real, Repeated Eigenvalues..........................191 5.3.6 Stability ..........................................194 5.4 Nonhomogeneous Systems .................................198 5.5 Three-Dimensional Systems................................204 6. Nonlinear Systems..........................................209 6.1 Nonlinear Models.........................................209 6.1.1 Phase Plane Phenomena ............................209 6.1.2 The Lotka–Volterra Model...........................217 6.1.3 Holling Functional Responses ........................221 6.1.4 An Epidemic Model ................................223 Contents ix 6.2 Numerical Methods.......................................229 6.3 Linearization and Stability.................................233 6.4 Periodic Solutions ........................................246 6.4.1 The Poincar´e–Bendixson Theorem....................249 Appendix A. References ........................................255 Appendix B. Computer Algebra Systems .......................257 B.1 Maple...................................................258 B.2 MATLAB ...............................................260 Appendix C. Sample Examinations .............................265 Appendix D. Solutions and Hints to Selected Exercises .........271 Index...........................................................287 Preface Therearemanyexcellenttextsonelementarydifferentialequationsdesignedfor thestandardsophomorecourse.However,inspiteofthefactthatmostcourses are one semester in length, the texts have evolved into calculus-like presen- tations that include a large collection of methods and applications, packaged with student manuals, and Web-based notes, projects, and supplements. All of this comes in several hundred pages of text with busy formats. Most students do not have the time or desire to read voluminous texts and explore internet supplements. The format of this differential equations book is different; it is a one-semester,brieftreatmentofthebasicideas,models,andsolutionmethods. Itslimitedcoverageplacesitsomewherebetweenanoutlineandadetailedtext- book.Ihavetriedtowriteconcisely,tothepoint,andinplainlanguage.Many workedexamplesandexercisesareincluded.Astudentwhoworksthroughthis primer will have the tools to go to the next level in applying differential equa- tionstoproblemsinengineering,science,andappliedmathematics.Itcangive some instructors, who want more concise coverage, an alternative to existing texts. The numerical solution of differential equations is a central activity in sci- ence and engineering, and it is absolutely necessary to teach students some aspects of scientific computation as early as possible. I tried to build in flex- ibility regarding a computer environment. The text allows students to use a calculator or a computer algebra system to solve some problems numerically and symbolically, and templates of MATLAB and Maple programs and com- mands are given in an appendix. The instructor can include as much of this, or as little of this, as he or she desires. For many years I have taught this material to students who have had a standard three-semester calculus sequence. It was well received by those who xii Preface appreciated having a small, definitive parcel of material to learn. Moreover, this text gives students the opportunity to start reading mathematics at a slightly higher level than experienced in pre-calculus and calculus. Therefore the book can be a bridge in their progress to study more advanced material at the junior–senior level, where books leave a lot to the reader and are not packaged in elementary formats. Chapters 1, 2, 3, 5, and 6 should be covered in order. They provide a route to geometric understanding, the phase plane, and the qualitative ideas that are important in differential equations. Included are the usual treatments of separable and linear first-order equations, along with second-order linear ho- mogeneous and nonhomogeneous equations. There are many applications to ecology, physics, engineering, and other areas. These topics will give students key skills in the subject. Chapter 4, on Laplace transforms, can be covered at any time after Chapter 3, or even omitted. Always an issue in teaching differ- ential equations is how much linear algebra to cover. In two extended sections inChapter5weintroduceamoderateamountofmatrixtheory,includingsolv- ing linear systems, determinants, and the eigenvalue problem. In spite of the book’s brevity, it still contains slightly more material than can be comfortably covered in a single three-hour semester course. Generally, I assign most of the exercises; hints and solutions for selected problems are given in Appendix D. I welcome suggestions, comments, and corrections. Contact information is on my Web site: http://www.math.unl.edu/˜dlogan, where additional items may be found. I would like to thank John Polking at Rice University for permitting me to use his MATLAB program pplane7 to draw some of the phase plane diagrams and Mark Spencer at Springer for his enthusiastic support of this project. Fi- nally, I would like to thank Tess for her continual encouragement and support for my work. David Logan Lincoln, Nebraska