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Differential Equations


and Boundary Value


Problems


B O Y C E | D I P R I M A | M E A D E


11th Edition


Elementary


www.konkur.in


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Elementary Differential Equations and Boundary Value Problems


Eleventh Edition


WILLIAM E. BOYCE


Edward P. Hamilton Professor Emeritus Department of Mathematical Sciences


Rensselaer Polytechnic Institute


RICHARD C. DIPRIMA


formerly Eliza Ricketts Foundation Professor Department of Mathematical Sciences


Rensselaer Polytechnic Institute


DOUGLAS B. MEADE


Department of Mathematics University of South Carolina - Columbia


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To Elsa, Betsy, and in loving memory of Maureen


To Siobhan, James, Richard Jr., Carolyn, Ann, Stuart,


Michael, Marybeth, and Bradley


And to the next generation:


Charles, Aidan, Stephanie, Veronica, and Deirdre


www.konkur.in


The Authors


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, and W.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


Laboratory Workbook (Wiley 1992), which received the


EDUCOM Best Mathematics Curricular Innovation Award


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


Faculty Award given by Rensselaer.


RICHARD C. DIPRIMA (deceased) received his B.S., M.S.,


and Ph.D. degrees in Mathematics from Carnegie-Mellon


University. He joined the faculty of Rensselaer Polytechnic


Institute after holding research positions at MIT, Harvard,


and Hughes Aircraft. He held the Eliza Ricketts Foundation


Professorship of Mathematics at Rensselaer, was a fellow of


the American Society of Mechanical Engineers, the American


Academy of Mechanics, and the American Physical Society.


He was also a member of the American Mathematical Society,


the Mathematical Association of America, and the Society


for Industrial and Applied Mathematics. He served as the


Chairman of the Department of Mathematical Sciences at


Rensselaer, as President of the Society for Industrial and


Applied Mathematics, and as Chairman of the Executive


Committee of the Applied Mechanics Division of ASME.


In 1980, he was the recipient of the William H. Wiley


Distinguished Faculty Award given byRensselaer. He received


Fulbright fellowships in 1964--65 and 1983 and a Guggenheim


fellowship in 1982--83. He was the author of numerous


technical papers in hydrodynamic stability and lubrication


theory and two texts on differential equations and boundary


value problems. Professor DiPrima died on September 10,


1984.


DOUGLAS B. MEADE received B.S. degrees in


Mathematics and Computer Science from Bowling Green


State University, an M.S. in Applied Mathematics from


Carnegie Mellon University, and a Ph.D. in mathematics


from Carnegie Mellon University. After a two-year stint


at Purdue University, he joined the mathematics faculty at


the University of South Carolina, where he is currently an


Associate Professor of mathematics and the Associate Dean for


Instruction, Curriculum, and Assessment in the College of Arts


and Sciences. He is a member of the American Mathematical


Society, Mathematics Association of America, and Society


for Industrial and Applied Mathematics; in 2016 he was


named an ICTCM Fellow at the International Conference on


Technology in Collegiate Mathematics (ICTCM). His primary


research interests are in the numerical solution of partial


differential equations arising from wave propagation problems


in unbounded domains and from population models for


infectious diseases. He is also well-known for his educational


uses of computer algebra systems, particularly Maple.


These include Getting Started with Maple (with M. May,


C-K. Cheung, and G. E. Keough, Wiley, 2009, ISBN 978-0-


470-45554-8), Engineer’s Toolkit: Maple for Engineers (with


E. Bourkoff, Addison-Wesley, 1998, ISBN 0-8053-6445-5),


and numerous Maple supplements for numerous calculus,


linear algebra, and differential equations textbooks - including


previous editions of this book. He was a member of the


MathDL New Collections Working Group for Single Variable


Calculus, and chaired the Working Groups for Differential


Equations and Linear Algebra. The NSF is partially supporting


his work, together with Prof. Philip Yasskin (Texas A&M), on


the Maplets for Calculus project.


vi


www.konkur.in


Preface


As we have prepared an updated edition our first priorities


are to preserve, and to enhance, the qualities that have made


previous editions so successful. In particular, we adopt the


viewpoint of an applied mathematician with diverse interests


in differential equations, ranging from quite theoretical to


intensely practical--and usually a combination of both. Three


pillars of our presentation of the material are methods


of solution, analysis of solutions, and approximations of


solutions. Regardless of the specific viewpoint adopted, we


have sought to ensure the exposition is simultaneously correct


and complete, but not needlessly abstract.


The intended audience is undergraduate STEM students


whose degree program includes an introductory course in


differential equations during the first two years. The essential


prerequisite is a working knowledge of calculus, typically a


two- or three-semester course sequence or an equivalent.While


a basic familiarity with matrices is helpful, Sections 7.2 and 7.3


provide an overview of the essential linear algebra ideas needed


for the parts of the book that deal with systems of differential


equations (the remainder of Chapter 7, Section 8.5, and


Chapter 9).


A strength of this book is its appropriateness in a


wide variety of instructional settings. In particular, it allows


instructors flexibility in the selection of and the ordering of


topics and in the use of technology. The essential core material


is Chapter 1, Sections 2.1 through 2.5, and Sections 3.1 through


3.5. After completing these sections, the selection of additional


topics, and the order and depth of coverage are generally at


the discretion of the instructor. Chapters 4 through 11 are


essentially independent of each other, except that Chapter 7


should precede Chapter 9, and Chapter 10 should precede


Chapter 11.


A particularly appealing aspect of differential equations


is that even the simplest differential equations have a direct


correspondence to realistic physical phenomena: exponential


growth and decay, spring-mass systems, electrical circuits,


competitive species, and wave propagation. More complex


natural processes can often be understood by combining and


building upon simpler and more basic models. A thorough


knowledge of these basic models, the differential equations


that describe them, and their solutions--either explicit solutions


or qualitative properties of the solution--is the first and


indispensable step toward analyzing the solutions of more


complex and realistic problems. The modeling process is


detailed in Chapter 1 and Section 2.3. Careful constructions


of models appear also in Sections 2.5, 3.7, 9.4, 10.5, and


10.7 (and the appendices to Chap er 10). Various problem sets


throughout the book include problems that involve modeling


to formulate an appropriate differential equation, and then


to solve it or to determine some qualitative properties of its


solution. The primary purposes of these applied problems are


to provide students with hands-on experience in the derivation


of differential equations, and to convince them that differential


equations arise naturally in a wide variety of real-world


applications.


Another important concept emphasized repeatedly


throughout the book is the transportability of mathematical


knowledge. While a specific solution method applies to only a


particular class of differential equations, it can be used in any


application in which that particular type of differential equation


arises. Once this point is made in a convincing manner, we


believe that it is unnecessary to provide specific applications of


every method of solution or type of equation that we consider.


This decision helps to keep this book to a reasonable size, and


allows us to keep the primary emphasis on the development


of more solution methods for additional types of differential


equations.


From a student’s point of view, the problems that are


assigned as homework and that appear on examinations define


the course. We believe that the most outstanding feature of


this book is the number, and above all the variety and range,


of the problems that it contains. Many problems are entirely


straightforward, but many others are more challenging, and


some are fairly open-ended and can even serve as the basis


for independent student projects. The observant reader will


notice that there are fewer problems in this edition than in


previous editions; many of these problems remain available


to instructors via the WileyPlus course. The remaining 1600


problems are still far more problems than any instructor can


use in any given course, and this provides instructors with a


multitude of choices in tailoring their course to meet their own


goals and the needs of their students. The answers to almost all


of these problems can be found in the pages at the back of the


book; full solutions are in either the Student’s Solution Manual


or the Instructor’s Solution Manual.


While we make numerous references to the use of


technology, we do so without limiting instructor freedom to


use as much, or as little, technology as they desire. Appropriate


technologies include advanced graphing calculators (TI


Nspire), a spreadsheet (Excel), web-based resources (applets),


computer algebra systems, (Maple, Mathematica, Sage),


scientific computation systems (MATLAB), or traditional


programming (FORTRAN, Javascript, Python). Problems


marked with a G are ones we believe are best approached with


a graphical tool; those marked with a N are best solved with the


use of a numerical tool. Instructors should consider setting their


own policies, consistent with their interests and intents about


student use of technology when completing assigned problems.


Many problems in this book are best solved through


a combination of analytic, graphic, and numeric methods.


Pencil-and-paper methods are used to develop a model that


is best solved (or analyzed) using a symbolic or graphic


tool. The quantitative results and graphs, frequently produced


using computer-based resources, serve to illustrate and to


clarify conclusions that might not be readily apparent from


a complicated explicit solution formula. Conversely, the


vii


www.konkur.in


viii PREFACE


implementation of an efficient numerical method to obtain


an approximate solution typically requires a good deal of


preliminary analysis--to determine qualitative features of the


solution as a guide to computation, to investigate limiting


or special cases, or to discover ranges of the variables or


parameters that require an appropriate combination of both


analytic and numeric computation. Good judgment may well


be required to determine the best choice of solution methods


in each particular case. Within this context we point out that


problems that request a “sketch” are generally intended to


be completed without the use of any technology (except your


writing device).


We believe that it is important for students to understand


that (except perhaps in courses on differential equations) the


goal of solving a differential equation is seldom simply to


obtain the solution. Rather, we seek the solution in order to


obtain insight into the behavior of the process that the equation


purports to model. In other words, the solution is not an end


in itself. Thus, we have included in the text a great many


problems, as well as some examples, that call for conclusions


to be drawn about the solution. Sometimes this takes the form


of finding the value of the independent variable at which the


solution has a certain property, or determining the long-term


behavior of the solution. Other problems ask for the effect of


variations in a parameter, or for the determination of all values


of a parameter at which the solution experiences a substantial


change. Such problems are typical of those that arise in the


applications of differential equations, and, depending on the


goals of the course, an instructor has the option of assigning as


few or as many of these problems as desired.


Readers familiar with the preceding edition will observe


that the general structure of the book is unchanged. The


minor revisions that we have made in this edition are in


many cases the result of suggestions from users of earlier


editions. The goals are to improve the clarity and readability of


our presentation of basic material about differential equations


and their applications. More specifically, the most important


revisions include the following:


1. Chapter 1 has been rewritten. Instead of a separate section


on the History of Differential Equations, this material


appears in three installments in the remaining three


section.


2. Additional words of explanation and/or more explicit


details in the steps in a derivation have been added


throughout each chapter. These are too numerous and


widespread to mention individually, but collectively they


should help to make the book more readable for many


students.


3. There are about forty new or revised problems scattered


throughout the book. The total number of problems has


been reduced by about 400 problems, which are still


available throughWileyPlus, leaving about 1600 problems


in print.


4. There are new examples in Sections 2.1, 3.8, and 7.5.


5. The majority (is this correct?) of the figures have been


redrawn, mainly by the use full color to allow for easier


identification of critical properties of the solution. In


addition, numerous captions have been expanded to clarify


the purpose of the figure without requiring a search of the


surrounding text.


6. There are several new references, and some others have


been updated.


The authors have found differential equations to be a


never-ending source of interesting, and sometimes surprising,


results and phenomena. We hope that users of this book, both


students and instructors, will share our enthusiasm for the


subject.


William E. Boyce and Douglas B. Meade


Watervliet, New York and Columbia, SC


29 August 2016


Supplemental Resources for


Instructors and Students


An Instructor’s Solutions Manual, ISBN 978-1-119-16976-5,


includes solutions for all problems not contained in the Student


Solutions Manual.


A Student Solutions Manual, ISBN 978-1-119-16975-8,


includes solutions for selected problems in the text.


A Book Companion Site, www.wiley.com/college/boyce,


provides a wealth of resources for students and instructors,


including


• PowerPoint slides of important definitions, examples, and


theorems from the book, as well as graphics for presentation


in lectures or for study and note taking.


• Chapter Review Sheets, which enable students to test their


knowledge of key concepts. For further review, diagnostic


feedback is provided that refers to pertinent sections in the


text.


• Mathematica, Maple, and MATLAB data files for selected


problems in the text providing opportunities for further


exploration of important concepts.


• Projects that deal with extended problems normally not


included among traditional topics in differential equations,


many involving applications from a variety of disciplines.


These vary in length and complexity, and they can be


assigned as individual homework or as group assignments.


A series of supplemental guidebooks, also published by John


Wiley & Sons, can be used with Boyce/DiPrima/Meade in


order to incorporate computing technologies into the course.


These books emphasize numerical methods and graphical


analysis, showing how these methods enable us to interpret


solutions of ordinary differential equations (ODEs) in the real


world. Separate guidebooks cover each of the three major


mathematical software formats, but the ODE subject matter is


the same in each.


• Hunt, Lipsman, Osborn, and Rosenberg, Differential


Equations with MATLAB , 3rd ed., 2012, ISBN 978-1-118-


37680-5


www.konkur.in


http://www.wiley.com/college/boyce

PREFACE ix


• Hunt, Lardy, Lipsman, Osborn, and Rosenberg, Differential


Equations with Maple, 3rd ed., 2008, ISBN 978-0-471-


77317-7


• Hunt, Outing, Lipsman, Osborn, and Rosenberg,


Differential Equations with Mathematica, 3rd ed., 2009,


ISBN 978-0-471-77316-0


WileyPLUS WileyPLUS is an innovative, research-based online environment for effective teaching and learning.


WileyPLUS builds students’ confidence because it takes


the guesswork out of studying by providing students with a


clear roadmap: what to do, how to do it, if they did it right.


Students will take more initiative so you’ll have greater impact


on their achievement in the classroom and beyond.


WileyPLUS, is loaded with all of the supplements above,


and it also features


• The E-book, which is an exact version of the print text


but also features hyperlinks to questions, definitions, and


supplements for quicker and easier support.


• Guided Online (GO) Exercises, which prompt students to


build solutions step-by-step. Rather than simply grading


an exercise answer as wrong, GO problems show students


precisely where they are making a mistake.


• Homework management tools, which enable instructors


easily to assign and grade questions, as well as to gauge


student comprehension.


• QuickStart pre-designed reading and homework assign


ments. Use them as is, or customize them to fit the needs of


your classroom.


Acknowledgments It is a pleasure to express my appreciation to the many people who


have generously assisted in various ways in the preparation of this


book.


To the individuals listed below, who reviewed the manuscript


and/or provided valuable suggestions for its improvement:


Irina Gheorghiciuc, Carnegie Mellon University


Bernard Brooks, Rochester Institute of Technology


James Moseley, West Virginia University


D. Glenn Lasseigne, Old Dominion University


Stephen Summers, University of Florida


Fabio Milner, Arizona State University


Mohamed Boudjelkha, Rensselaer Polytechnic Institute


Yuval Flicker, The Ohio State University


Y. Charles Li, University of Missouri, Columbia


Will Murray, California State University, Long Beach


Yue Zhao, University of Central Florida


Vladimir Shtelen, Rutgers University


Zhilan Feng, Purdue University


Mathew Johnson, University of Kansas


Bulent Tosun, University of Alabama


Juha Pohjanpelto, Oregon State University


Patricia Diute, Rochester Institute of Technology


Ning Ju, Oklahoma State University


Ian Christie, West Virginia University


Jonathan Rosenberg, University of Maryland


Irina Kogan, North Carolina State University


To our colleagues and students at Rensselaer and The University


of South Carolina, whose suggestions and reactions through the years


have donemuch to sharpen our knowledge of differential equations, as


well as our ideas on how to present the subject.


To those readers of the preceding edition who called errors or


omissions to our attention.


To Tom Polaski (Winthrop University), who is primarily


responsible for the revision of the Instructor’s Solutions Manual and the Student Solutions Manual.


To Mark McKibben (West Chester University), who checked the


answers in the back of the text and the Instructor’s Solutions Manual for accuracy, and carefully checked the entire manuscript.


To the editorial and production staff of John Wiley & Sons, who


have always been ready to offer assistance and have displayed the


highest standards of professionalism.


The last, but most important, people we want to thank are our


wives: Elsa, for discussing questions both mathematical and stylistic


and above all for her unfailing support and encouragement, and Betsy,


for her encouragement, patience and understanding.


WILLIAM E. BOYCE AND DOUGLAS B. MEADE


www.konkur.in


Brief Contents


PREFACE vii


1 Introduction 1


2 First-Order Differential Equations 24


3 Second-Order Linear Differential Equations 103


4 Higher-Order Linear Differential Equations 169


5 Series Solutions of Second-Order Linear Equations 189


6 The Laplace Transform 241


7 Systems of First-Order Linear Equations 281


8 Numerical Methods 354


9 Nonlinear Differential Equations and Stability 388


10 Partial Differential Equations and Fourier Series 463


11 Boundary Value Problems and Sturm-Liouville Theory 529


ANSWERS TO PROBLEMS 573


INDEX 60


x


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Contents


PREFACE vii


1 Introduction 1


1.1 Some Basic Mathematical Models; Direction


Fields 1


1.2 Solutions of Some Differential Equations 9


1.3 Classification of Differential Equations 16


2 First-Order Differential Equations 24


2.1 Linear Differential Equations; Method of


Integrating Factors 24


2.2 Separable Differential Equations 33


2.3 Modeling with First-Order Differential


Equations 39


2.4 Differences Between Linear and Nonlinear


Differential Equations 51


2.5 Autonomous Differential Equations and


Population Dynamics 58


2.6 Exact Differential Equations and Integrating


Factors 70


2.7 Numerical Approximations: Euler’s Method 76


2.8 The Existence and Uniqueness Theorem 83


2.9 First-Order Difference Equations 91


3 Second-Order Linear Differential Equations 103


3.1 Homogeneous Differential Equations with


Constant Coefficients 103


3.2 Solutions of Linear Homogeneous Equations; the


Wronskian 110


3.3 Complex Roots of the Characteristic Equation


120


3.4 Repeated Roots; Reduction of Order 127


3.5 Nonhomogeneous Equations; Method of


Undetermined Coefficients 133


3.6 Variation of Parameters 142


3.7 Mechanical and Electrical Vibrations 147


3.8 Forced Periodic Vibrations 159


4 Higher-Order Linear Differential Equations 169


4.1 General Theory of nth Order Linear Differential


Equations 169


4.2 Homogeneous Differential Equations with


Constant Coefficients 174


4.3 The Method of Undetermined Coefficients 181


4.4 The Method of Variation of Parameters 185


5 Series Solutions of Second-Order Linear Equations 189


5.1 Review of Power Series 189


5.2 Series Solutions Near an Ordinary Point,


Part I 195


5.3 Series Solutions Near an Ordinary Point,


Part II 205


5.4 Euler Equations; Regular Singular Points 211


5.5 Series Solutions Near a Regular Singular Point,


Part I 219


5.6 Series Solutions Near a Regular Singular Point,


Part II 224


5.7 Bessel’s Equation 230


6 The Laplace Transform 241


6.1 Definition of the Laplace Transform 241


6.2 Solution of Initial Value Problems 248


6.3 Step Functions 257


6.4 Differential Equations with Discontinuous Forcing


Functions 264


6.5 Impulse Functions 270


6.6 The Convolution Integral 275


7 Systems of First-Order Linear Equations 281


7.1 Introduction 281


7.2 Matrices 286


7.3 Systems of Linear Algebraic Equations; Linear


Independence, Eigenvalues, Eigenvectors 295


7.4 Basic Theory of Systems of First-Order Linear


Equations 304


7.5 Homogeneous Linear Systems with Constant


Coefficients 309


7.6 Complex-Valued Eigenvalues 319


7.7 Fundamental Matrices 329


7.8 Repeated Eigenvalues 337


7.9 Nonhomogeneous Linear Systems 345


8 Numerical Methods 354


8.1 The Euler or Tangent Line Method 354


8.2 Improvements on the Euler Method 363


xi


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xii CONTENTS


8.3 The Runge-Kutta Method 367


8.4 Multistep Methods 371


8.5 Systems of First-Order Equations 376


8.6 More on Errors; Stability 378


9 Nonlinear Differential Equations and Stability 388


9.1 The Phase Plane: Linear Systems 388


9.2 Autonomous Systems and Stability 398


9.3 Locally Linear Systems 407


9.4 Competing Species 417


9.5 Predator-Prey Equations 428


9.6 Liapunov’s Second Method 435


9.7 Periodic Solutions and Limit Cycles 444


9.8 Chaos and Strange Attractors: The Lorenz


Equations 454


10 Partial Differential Equations and Fourier Series 463


10.1 Two-Point Boundary Value Problems 463


10.2 Fourier Series 469


10.3 The Fourier Convergence Theorem 477


10.4 Even and Odd Functions 482


10.5 Separation of Variables; Heat Conduction


in a Rod 488


10.6 Other Heat Conduction Problems 496


10.7 The Wave Equation: Vibrations of an Elastic


String 504


10.8 Laplace's Equation 514


11 Boundary Value Problems and Sturm-Liouville Theory 529


11.1 The Occurrence of Two-Point Boundary Value


Problems 529


11.2 Sturm-Liouville Boundary Value Problems 535


11.3 NonhomogeneousBoundaryValueProblems 545


11.4 Singular Sturm-Liouville Problems 556


11.5 Further Remarks on the Method of Separation


of Variables: A Bessel Series Expansion 562


11.6 Series of Orthogonal Functions: Mean


Convergence 566


ANSWERS TO PROBLEMS 573


INDEX 60


www.konkur.in


CHAPTER1


Introduction


In this first chapter we provide a foundation for your study of differential equations in several


different ways. First, we use two problems to illustrate some of the basic ideas that we


will return to, and elaborate upon, frequently throughout the remainder of the book. Later,


to provide organizational structure for the book, we indicate several ways of classifying


differential equations.


The study of differential equations has attracted the attention of many of the world’s


greatest mathematicians during the past three centuries. On the other hand, it is important


to recognize that differential equations remains a dynamic field of inquiry today, with many


interesting open questions. We outline some of the major trends in the historical development


of the subject and mention a few of the outstanding mathematicians who have contributed to


it. Additional biographical information about some of these contributors will be highlighted


at appropriate times in later chapters.


1.1 Some Basic Mathematical Models;


Direction Fields


Before embarking on a serious study of differential equations (for example, by reading this


book ormajor portions of it), you should have some idea of the possible benefits to be gained by


doing so. For some students the intrinsic interest of the subject itself is enough motivation, but


for most it is the likelihood of important applications to other fields that makes the undertaking


worthwhile.


Many of the principles, or laws, underlying the behavior of the natural world


are statements or relations involving rates at which things happen. When expressed in


mathematical terms, the relations are equations and the rates are derivatives. Equations


containing derivatives are differential equations. Therefore, to understand and to investigate


problems involving the motion of fluids, the flow of current in electric circuits, the dissipation


of heat in solid objects, the propagation and detection of seismic waves, or the increase


or decrease of populations, among many others, it is necessary to know something about


differential equations.


A differential equation that describes some physical process is often called a


mathematical model of the process, and many such models are discussed throughout this


book. In this section we begin with two models leading to equations that are easy to solve. It


is noteworthy that even the simplest differential equations provide useful models of important


physical processes.


EXAMPLE 1 | A Falling Object


Suppose that an object is falling in the atmosphere near sea level. Formulate a differential equation


that describes the motion.


▼ 1


www.konkur.in


2 CHAPTER 1 Introduction


▼ Solution:


We begin by introducing letters to represent various quantities that may be of interest in this problem.


The motion takes place during a certain time interval, so let us use t to denote time. Also, let


us use v to represent the velocity of the falling object. The velocity will presumably change with


time, so we think of v as a function of t ; in other words, t is the independent variable and v is the


dependent variable. The choice of units of measurement is somewhat arbitrary, and there is nothing


in the statement of the problem to suggest appropriate units, so we are free to make any choice that


seems reasonable. To be specific, let us measure time t in seconds and velocity v in meters/second.


Further, we will assume that v is positive in the downward direction---that is, when the object is


falling.


The physical law that governs the motion of objects is Newton’s second law, which states that


the mass of the object times its acceleration is equal to the net force on the object. In mathematical


terms this law is expressed by the equation


F = ma, (1)


where m is the mass of the object, a is its acceleration, and F is the net force exerted on the object. To


keep our units consistent, we will measure m in kilograms, a in meters/second2, and F in newtons.


Of course, a is related to v by a = dv/dt , so we can rewrite equation (1) in the form


F = m dv


dt . (2)


Next, consider the forces that act on the object as it falls. Gravity exerts a force equal to


the weight of the object, or mg, where g is the acceleration due to gravity. In the units we


have chosen, g has been determined experimentally to be approximately equal to 9.8 m/s2 near


the earth’s surface.


There is also a force due to air resistance, or drag, that is more difficult to model. This is not


the place for an extended discussion of the drag force; suffice it to say that it is often assumed that


the drag is proportional to the velocity, and we will make that assumption here. Thus the drag force


has the magnitude γ v , where γ is a constant called the drag coefficient. The numerical value of the drag coefficient varies widely from one object to another; smooth streamlined objects have much


smaller drag coefficients than rough blunt ones. The physical units for γ are mass/time, or kg/s for this problem; if these units seem peculiar, remember that γ v must have the units of force, namely, kg·m/s2.


In writing an expression for the net force F , we need to remember that gravity always acts in


the downward (positive) direction, whereas, for a falling object, drag acts in the upward (negative)


direction, as shown in Figure 1.1.1. Thus


F = mg − γ v (3)


and equation (2) then becomes


m dv


dt = mg − γ v. (4)


Differential equation (4) is a mathematical model for the velocity v of an object falling in the


atmosphere near sea level. Note that themodel contains the three constantsm, g, and γ . The constants m and γ depend very much on the particular object that is falling, and they are usually different for different objects. It is common to refer to them as parameters, since they may take on a range of


values during the course of an experiment. On the other hand, g is a physical constant, whose value


is the same for all objects.


γ υ


m


mg


FIGURE 1.1.1 Free-body diagram of the forces on a falling object.


www.konkur.in


1.1 Some Basic Mathematical Models; Direction Fields 3


To solve equation (4), we need to find a function v = v( t) that satisfies the equation. It


is not hard to do this, and we will show you how in the next section. For the present, however,


let us see what we can learn about solutions without actually finding any of them. Our task


is simplified slightly if we assign numerical values to m and γ , but the procedure is the same regardless of which values we choose. So, let us suppose that m = 10 kg and γ = 2 kg/s. Then equation (4) can be rewritten as


dv


dt = 9.8 −


v


5 . (5)


EXAMPLE 2 | A Falling Object (continued)


Investigate the behavior of solutions of equation (5) without solving the differential equation.


Solution:


First let us consider what information can be obtained directly from the differential equation itself.


Suppose that the velocity v has a certain given value. Then, by evaluating the right-hand side of


differential equation (5), we can find the corresponding value of dv/dt . For instance, if v = 40, then dv/dt = 1.8. This means that the slope of a solution v = v( t) has the value 1.8 at any point where v = 40. We can display this information graphically in the tv-plane by drawing short line segments


with slope 1.8 at several points on the line v = 40. (See Figure 1.1.2(a)). Similarly, when v = 50,


then dv/dt = −0.2, and when v = 60, then dv/dt = −2.2, so we draw line segments with slope −0.2 at several points on the line v = 50 (see Figure 1.1.2(b)) and line segments with slope −2.2 at several points on the line v = 60 (see Figure 1.1.2(c)). Proceeding in the same way with other values


of v we create what is called a direction field, or a slope field. The direction field for differential


equation (5) is shown in Figure 1.1.3.


Remember that a solution of equation (5) is a function v = v( t) whose graph is a curve in


the tv-plane. The importance of Figure 1.1.3 is that each line segment is a tangent line to one


of these solution curves. Thus, even though we have not found any solutions, and no graphs of


solutions appear in the figure, we can nonetheless draw some qualitative conclusions about the


behavior of solutions. For instance, if v is less than a certain critical value, then all the line segments


have positive slopes, and the speed of the falling object increases as it falls. On the other hand, if v


is greater than the critical value, then the line segments have negative slopes, and the falling object


slows down as it falls. What is this critical value of v that separates objects whose speed is increasing


from those whose speed is decreasing? Referring again to equation (5), we ask what value of v will


cause dv/dt to be zero. The answer is v = (5) (9.8) = 49 m/s. In fact, the constant function v( t) = 49 is a solution of equation (5). To verify this statement,


substitute v( t) = 49 into equation (5) and observe that each side of the equation is zero. Because


it does not change with time, the solution v( t) = 49 is called an equilibrium solution. It is


the solution that corresponds to a perfect balance between gravity and drag. In Figure 1.1.3 we show


the equilibrium solution v( t) = 49 superimposed on the direction field. From this figure we can


draw another conclusion, namely, that all other solutions seem to be converging to the equilibrium


solution as t increases. Thus, in this context, the equilibrium solution is often called the terminal


velocity.


t


45


40


50


55


60 υ


2 4 6 8 10


All slopes 1.8 All slopes –0.2 All slopes –2.2


t


45


40


50


55


60 υ


2 4 6 8 10t


45


40


50


55


60 υ


2 4 6 8 10


(a) (b) (c)


FIGURE 1.1.2 Assembling a direction field for equation (5): dv/dt = 9.8−v/5. (a) when v = 40,


dv/dt = 1.8, (b) when v = 50, dv/dt = −0.2, and (c) when v = 60, dv/dt = −2.2.




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4 CHAPTER 1 Introduction




2 4 t6 8 10


50


45


40


55


60


υ


FIGURE 1.1.3 Direction field and equilibrium solution for equation (5):


dv/dt = 9.8 − v/5.


The approach illustrated in Example 2 can be applied equally well to the more general


differential equation (4), where the parameters m and γ are unspecified positive numbers. The results are essentially identical to those of Example 2. The equilibrium solution of equation (4)


is the constant solution v( t) = mg/γ . Solutions below the equilibrium solution increase with time, and those above it decrease with time. As a result, we conclude that all solutions approach


the equilibrium solution as t becomes large.


Direction Fields. Direction fields are valuable tools in studying the solutions of differential


equations of the form


dy


dt = f ( t , y) , (6)


where f is a given function of the two variables t and y, sometimes referred to as the rate


function. A direction field for equations of the form (6) can be constructed by evaluating f


at each point of a rectangular grid. At each point of the grid, a short line segment is drawn


whose slope is the value of f at that point. Thus each line segment is tangent to the graph


of the solution passing through that point. A direction field drawn on a fairly fine grid gives


a good picture of the overall behavior of solutions of a differential equation. Usually a grid


consisting of a few hundred points is sufficient. The construction of a direction field is often


a useful first step in the investigation of a differential equation.


Two observations are worth particular mention. First, in constructing a direction field, we


do not have to solve equation (6); we just have to evaluate the given function f ( t , y) many


times. Thus direction fields can be readily constructed even for equations that may be quite


difficult to solve. Second, repeated evaluation of a given function and drawing a direction field


are tasks for which a computer or other computational or graphical aid are well suited. All the


direction fields shown in this book, such as the one in Figures 1.1.2 and 1.1.3, were computer


generated.


Field Mice and Owls. Now let us look at another, quite different example. Consider a


population of field mice that inhabit a certain rural area. In the absence of predators we assume


that the mouse population increases at a rate proportional to the current population. This


assumption is not a well-established physical law (as Newton’s law ofmotion is in Example 1),


but it is a common initial hypothesis1 in a study of population growth. If we denote time by t


and the mouse population at time t by p( t) , then the assumption about population growth can


be expressed by the equation


dp


dt = r p, (7)


......................................................................................................................................................................... 1A better model of population growth is discussed in Section 2.5.


www.konkur.in


1.1 Some Basic Mathematical Models; Direction Fields 5


where the proportionality factor r is called the rate constant or growth rate. To be specific,


suppose that time is measured in months and that the rate constant r has the value 0.5/month.


Then the two terms in equation (7) have the units of mice/month.


Now let us add to the problem by supposing that several owls live in the same


neighborhood and that they kill 15 field mice per day. To incorporate this information into


the model, we must add another term to the differential equation (7), so that it becomes


dp


dt =


p


2 − 450. (8)


Observe that the predation term is −450 rather than −15 because time is measured in months,


so the monthly predation rate is needed.


EXAMPLE 3


Investigate the solutions of differential equation (8) graphically.

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