5128_FM_TE_ppi-xxiv 2/3/06 3:32 PM Page iv Contents CHAPTER 1 Prerequisites for Calculus 2 1.1 Lines 3 •Increments •Slope of a Line •Parallel and Perpendicular Lines •Equations of Lines •Applications 1.2 Functions and Graphs 12 •Functions •Domains and Ranges •Viewing and Interpreting Graphs •Even Functions and Odd Functions—Symmetry •Functions Defined in Pieces • Absolute Value Function •Composite Functions 1.3 Exponential Functions 22 •Exponential Growth •Exponential Decay •Applications •The Number e 1.4 Parametric Equations 30 •Relations •Circles •Ellipses •Lines and Other Curves 1.5 Functions and Logarithms 37 •One-to-One Functions •Inverses •Finding Inverses •Logarithmic Functions •Properties of Logarithms •Applications 1.6 Trigonometric Functions 46 •Radian Measure •Graphs of Trigonometric Functions •Periodicity •Even and Odd Trigonometric Functions •Transformations of Trigonometric Graphs • Inverse Trigonometric Functions Key Terms 55 Review Exercises 56 CHAPTER 2 Limits and Continuity 58 2.1 Rates of Change and Limits 59 •Average and Instantaneous Speed •Definition of Limit •Properties of Limits •One-sided and Two-sided Limits •Sandwich Theorem 2.2 Limits Involving Infinity 70 •Finite Limits as x→!"•Sandwich Theorem Revisited •Infinite Limits as x→a•End Behavior Models •“Seeing”Limits as x→!" 2.3 Continuity 78 •Continuity at a Point •Continuous Functions •Algebraic Combinations • Composites •Intermediate Value Theorem for Continuous Functions Every section throughout the book 2.4 Rates of Change and Tangent Lines 87 also includes “Exploration”and “Extending the Ideas”features which •Average Rates of Change •Tangent to a Curve •Slope of a Curve •Normal to follow the exercises. a Curve •Speed Revisited iv 5128_FM_TE_ppi-xxiv 1/18/06 1:07 PM Page v Key Terms 95 Review Exercises 95 CHAPTER 3 Derivatives 98 3.1 Derivative of a Function 99 •Definition of a Derivative •Notation •Relationship Between the Graphs of ƒand ƒ!•Graphing the Derivative from Data •One-sided Derivatives 3.2 Differentiability 109 •How ƒ!(a) Might Fail to Exist •Differentiability Implies Local Linearity • Derivatives on a Calculator •Differentiability Implies Continuity •Intermediate Value Theorem for Derivatives 3.3 Rules for Differentiation 116 •Positive Integer Powers,Multiples,Sums,and Differences •Products and Quotients •Negative Integer Powers of x•Second and Higher Order Derivatives 3.4 Velocity and Other Rates of Change 127 •Instantaneous Rates of Change •Motion along a Line •Sensitivity to Change •Derivatives in Economics 3.5 Derivatives of Trigonometric Functions 141 •Derivative of the Sine Function •Derivative of the Cosine Function •Simple Harmonic Motion •Jerk •Derivatives of Other Basic Trigonometric Functions 3.6 Chain Rule 148 •Derivative of a Composite Function •“Outside-Inside”Rule •Repeated Use of the Chain Rule •Slopes of Parametrized Curves •Power Chain Rule 3.7 Implicit Differentiation 157 •Implicitly Defined Functions •Lenses,Tangents,and Normal Lines • Derivatives of Higher Order •Rational Powers of Differentiable Functions 3.8 Derivatives of Inverse Trigonometric Functions 165 •Derivatives of Inverse Functions •Derivative of the Arcsine •Derivative of the Arctangent •Derivative of the Arcsecant •Derivatives of the Other Three 3.9 Derivatives of Exponential and Logarithmic Functions 172 •Derivative of ex•Derivative of ax•Derivative of ln x•Derivative of log x• a Power Rule for Arbitrary Real Powers Calculus at Work 181 Key Terms 181 Review Exercises 181 Contents v 5128_FM_TE_ppi-xxiv 1/18/06 1:08 PM Page vi CHAPTER 4 Applications of Derivatives 186 4.1 Extreme Values of Functions 187 •Absolute (Global) Extreme Values •Local (Relative) Extreme Values •Finding Extreme Values 4.2 Mean Value Theorem 196 •Mean Value Theorem •Physical Interpretation •Increasing and Decreasing Functions •Other Consequences 4.3 Connecting ƒ! and ƒ" with the Graph of ƒ 205 •First Derivative Test for Local Extrema •Concavity •Points of Inflection • Second Derivative Test for Local Extrema •Learning about Functions from Derivatives 4.4 Modeling and Optimization 219 •Examples from Mathematics •Examples from Business and Industry • Examples from Economics •Modeling Discrete Phenomena with Differentiable Functions 4.5 Linearization and Newton’s Method 233 •Linear Approximation •Newton’s Method •Differentials •Estimating Change with Differentials •Absolute,Relative,and Percentage Change •Sensitivity to Change 4.6 Related Rates 246 •Related Rate Equations •Solution Strategy •Simulating Related Motion Key Terms 255 Review Exercises 256 CHAPTER 5 The Definite Integral 262 5.1 Estimating with Finite Sums 263 •Distance Traveled •Rectangular Approximation Method (RAM) •Volume of a Sphere •Cardiac Output 5.2 Definite Integrals 274 •Riemann Sums •Terminology and Notation of Integration •Definite Integral and Area •Constant Functions •Integrals on a Calculator •Discontinuous Integrable Functions 5.3 Definite Integrals and Antiderivatives 285 •Properties of Definite Integrals •Average Value of a Function •Mean Value Theorem for Definite Integrals •Connecting Differential and Integral Calculus 5.4 Fundamental Theorem of Calculus 294 •Fundamental Theorem,Part 1 •Graphing the Function ∫axƒ(t)dt•Fundamental Theorem,Part 2 •Area Connection •Analyzing Antiderivatives Graphically vi Contents 5128_FM_TE_ppi-xxiv 1/18/06 1:08 PM Page vii 5.5 Trapezoidal Rule 306 •Trapezoidal Approximations •Other Algorithms •Error Analysis Key Terms 315 Review Exercises 315 Calculus at Work 319 CHAPTER 6 Differential Equations and Mathematical Modeling 320 6.1 Slope Fields and Euler’s Method 321 •Differential Equations •Slope Fields •Euler’s Method 6.2 Antidifferentiation by Substitution 331 •Indefinite Integrals •Leibniz Notation and Antiderivatives •Substitution in Indefinite Integrals •Substitution in Definite Integrals 6.3 Antidifferentiation by Parts 341 •Product Rule in Integral Form •Solving for the Unknown Integral •Tabular Integration •Inverse Trigonometric and Logarithmic Functions 6.4 Exponential Growth and Decay 350 •Separable Differential Equations •Law of Exponential Change •Continuously Compounded Interest •Radioactivity •Modeling Growth with Other Bases • Newton’s Law of Cooling 6.5 Logistic Growth 362 •How Populations Grow •Partial Fractions •The Logistic Differential Equation •Logistic Growth Models Key Terms 372 Review Exercises 372 Calculus at Work 376 CHAPTER 7 Applications of Definite Integrals 378 7.1 Integral As Net Change 379 •Linear Motion Revisited •General Strategy •Consumption Over Time •Net Change from Data •Work 7.2 Areas in the Plane 390 •Area Between Curves •Area Enclosed by Intersecting Curves •Boundaries with Changing Functions •Integrating with Respect to y•Saving Time with Geometry Formulas 7.3 Volumes 399 •Volume As an Integral •Square Cross Sections •Circular Cross Sections • Cylindrical Shells •Other Cross Sections Contents vii 5128_FM_TE_ppi-xxiv 1/18/06 1:08 PM Page viii 7.4 Lengths of Curves 412 •A Sine Wave •Length of Smooth Curve •Vertical Tangents,Corners,and Cusps 7.5 Applications from Science and Statistics 419 •Work Revisited •Fluid Force and Fluid Pressure •Normal Probabilities Calculus at Work 430 Key Terms 430 Review Exercises 430 CHAPTER 8 Sequences, L’Hôpital’s Rule, and Improper Integrals 434 8.1 Sequences 435 •Defining a Sequence •Arithmetic and Geometric Sequences •Graphing a Sequence •Limit of a Sequence 8.2 L’Hôpital’s Rule 444 • Indeterminate Form 0/0 •Indeterminate Forms #/#,#$0,and #%#• Indeterminate Forms 1#,00,#0 8.3 Relative Rates of Growth 453 •Comparing Rates of Growth •Using L’Hôpital’s Rule to Compare Growth Rates •Sequential versus Binary Search 8.4 Improper Integrals 459 •Infinite Limits of Integration •Integrands with Infinite Discontinuities •Test for Convergence and Divergence •Applications Key Terms 470 Review Exercises 470 CHAPTER 9 Infinite Series 472 9.1 Power Series 473 •Geometric Series •Representing Functions by Series •Differentiation and Integration •Identifying a Series 9.2 Taylor Series 484 •Constructing a Series •Series for sin xand cos x•Beauty Bare •Maclaurin and Taylor Series •Combining Taylor Series •Table of Maclaurin Series 9.3 Taylor’s Theorem 495 •Taylor Polynomials •The Remainder •Remainder Estimation Theorem • Euler’s Formula 9.4 Radius of Convergence 503 •Convergence •nth-Term Test •Comparing Nonnegative Series •Ratio Test • Endpoint Convergence viii Contents 5128_FM_TE_ppi-xxiv 1/18/06 1:08 PM Page ix 9.5 Testing Convergence at Endpoints 513 •Integral Test •Harmonic Series and p-series •Comparison Tests •Alternating Series •Absolute and Conditional Convergence •Intervals of Convergence • A Word of Caution Key Terms 526 Review Exercises 526 Calculus at Work 529 CHAPTER 10 Parametric, Vector, and Polar Functions 530 10.1 Parametric Functions 531 •Parametric Curves in the Plane •Slope and Concavity •Arc Length •Cycloids 10.2 Vectors in the Plane 538 •Two-Dimensional Vectors •Vector Operations •Modeling Planar Motion • Velocity,Acceleration,and Speed •Displacement and Distance Traveled 10.3 Polar Functions 548 •Polar Coordinates •Polar Curves •Slopes of Polar Curves •Areas Enclosed by Polar Curves •A Small Polar Gallery Key Terms 559 Review Exercises 560 APPENDIX A1 Formulas from Precalculus Mathematics 562 A2 Mathematical Induction 566 A3 Using the Limit Definition 569 A4 Proof of the Chain Rule 577 A5 Conic Sections 578 A6 Hyperbolic Functions 603 A7 A Brief Table of Integrals 612 Glossary 618 Additional Answers 629 Applications Index 691 Index 695 Contents ix 5128_Ch01_pp02-57.qxd 1/13/06 8:47 AM Page 2 1 Chapter Prerequisites for Calculus Exponential functions are used to model situations in which growth or decay change dramatically. Such situations are found in nuclear power plants, which contain rods of plutonium-239; an extremely toxic radioactive isotope. Operating at full capacity for one year, a 1,000 megawatt power plant discharges about 435 lb of plutonium-239. With a half-life of 24,400 years, how much of the isotope will remain after 1,000 years? This question can be answered with the mathematics covered in Section 1.3. 2 5128_Ch01_pp02-57.qxd 1/13/06 8:47 AM Page 3 Section 1.1 Lines 3 Chapter 1 Overview This chapter reviews the most important things you need to know to start learning calcu- lus. It also introduces the use of a graphing utility as a tool to investigate mathematical ideas,to support analytic work,and to solve problems with numerical and graphical meth- ods. The emphasis is on functions and graphs,the main building blocks of calculus. Functions and parametric equations are the major tools for describing the real world in mathematical terms,from temperature variations to planetary motions,from brain waves to business cycles, and from heartbeat patterns to population growth. Many functions have particular importance because of the behavior they describe. Trigonometric func- tions describe cyclic, repetitive activity; exponential, logarithmic, and logistic functions describe growth and decay; and polynomial functions can approximate these and most other functions. 1.1 Lines What you’ll learn about Increments • Increments One reason calculus has proved to be so useful is that it is the right mathematics for relat- • Slope of a Line ing the rate of change of a quantity to the graph of the quantity. Explaining that relation- ship is one goal of this book. It all begins with the slopes of lines. • Parallel and Perpendicular Lines When a particle in the plane moves from one point to another, the net changes or • Equations of Lines incrementsin its coordinates are found by subtracting the coordinates of its starting point from the coordinates of its stopping point. • Applications . . . and why Linear equations are used exten- DEFINITION Increments sively in business and economic If a particle moves from the point (x ,y ) to the point (x ,y ),the incrementsin its applications. 1 1 2 2 coordinates are !x"x !x and !y"y !y . 2 1 2 1 The symbols !xand !yare read “delta x”and “delta y.”The letter !is a Greek capital dfor “difference.”Neither !xnor !ydenotes multiplication; !xis not “delta times x”nor is !y“delta times y.” Increments can be positive,negative,or zero,as shown in Example 1. L EXAMPLE 1 Finding Increments y The coordinate increments from !4,!3"to (2,5) are P(x , y) 2 2 2 !x"2!4"!2, !y"5!!!3""8. !y " rise From (5,6) to (5,1),the increments are P1(x1, y1)!x " run Q(x2, y1) !x"5!5"0, !y"1!6"!5. Now try Exercise 1. x O Slope of a Line Figure 1.1 The slope of line Lis Each nonvertical line has a slope,which we can calculate from increments in coordinates. rise !y Let L be a nonvertical line in the plane and P (x , y ) and P (x , y ) two points on L m"##"##. 1 1 1 2 2 2 run !x (Figure 1.1). We call !y"y !y the risefrom P to P and !x"x !x the runfrom 2 1 1 2 2 1 5128_Ch01_pp02-57.qxd 1/13/06 8:47 AM Page 4 4 Chapter1 Prerequisites for Calculus P to P . Since Lis not vertical,!x!0 and we define the slope of Lto be the amount of 1 2 rise per unit of run. It is conventional to denote the slope by the letter m. L L 1 2 DEFINITION Slope Slope m Slope m 1 2 Let P (x ,y ) and P (x ,y ) be points on a nonvertical line,L.The slopeof Lis 1 1 1 2 2 2 m m 1 2 θ θ rise !y y %y 1 2 x m"&&"&&"&2 &1. 1 1 run !x x %x 2 1 Figure 1.2 If L !L ,then u "u and 1 2 1 2 A line that goes uphill as xincreases has a positive slope. A line that goes downhill as x m "m . Conversely,if m "m ,then 1 2 1 2 increases has a negative slope. A horizontal line has slope zero since all of its points have u "u and L !L . 1 2 1 2 the same y-coordinate,making !y"0. For vertical lines,!x"0 and the ratio !y#$xis undefined. We express this by saying that vertical lines have no slope. y Parallel and Perpendicular Lines L L 1 2 Parallel lines form equal angles with the x-axis (Figure 1.2). Hence, nonvertical parallel C lines have the same slope. Conversely,lines with equal slopes form equal angles with the Slope m1 !1 Slope m2 x-axis and are therefore parallel. h If two nonvertical lines L and L are perpendicular, their slopes m and m satisfy !1 !2 m m "%1,so each slope is 1the nega2tive reciprocalof the other: 1 2 x 1 2 O A D a B 1 1 m "%&&, m "%&&. 1 m 2 m Figure 1.3 !ADCis similar to !CDB. 2 1 Hence f1is also the upper angle in !CDB, The argument goes like this: In the notation of Figure 1.3, m1 " tanf1 " a#h, while where tanf1"a#h. m "tanf "%h#a.Hence,m m "(a#h)(%h#a) "%1. 2 2 1 2 Equations of Lines The vertical line through the point (a,b) has equation x"asince every x-coordinate on the line has the value a.Similarly,the horizontal line through (a,b) has equation y"b. y EXAMPLE 2 Finding Equations of Vertical and Horizontal Lines Along this line, The vertical and horizontal lines through the point (2,3) have equations x"2 and 6 x " 2. y"3,respectively (Figure 1.4). Now try Exercise 9. 5 We can write an equation for any nonvertical line L if we know its slope m and the 4 Along this line, coordinates of one point P (x ,y ) on it. If P(x,y) is anyother point on L,then 1 1 1 y " 3. 3 y%y (2, 3) &&1 "m, x%x 2 1 so that 1 y%y "m(x%x ) or y"m(x%x ) ’y . 1 1 1 1 x 0 1 2 3 4 DEFINITION Point-Slope Equation Figure 1.4 The standard equations for the vertical and horizontal lines through The equation the point (2,3) are x"2 and y"3. y"m(x%x ) ’y (Example 2) 1 1 is the point-slope equationof the line through the point (x ,y ) with slope m. 1 1 5128_Ch01_pp02-57.qxd 1/13/06 8:47 AM Page 5 Section 1.1 Lines 5 EXAMPLE 3 Using the Point-Slope Equation Write the point-slope equation for the line through the point (2,3) with slope !3"2. SOLUTION We substitute x #2,y #3,and m#!3"2 into the point-slope equation and obtain 1 1 3 3 y#!$$!x!2"%3 or y#!$$x%6. 2 2 Now try Exercise 13. y The y-coordinate of the point where a nonvertical line intersects the y-axis is the y-interceptof the line. Similarly,the x-coordinate of the point where a nonhorizontal line Slope m (x, y) intersects the x-axis is the x-intercept of the line. A line with slope m and y-intercept bpasses through (0,b) (Figure 1.5),so y = mx + b (0, b) y#m!x!0"%b, or,more simply, y#mx%b. b x DEFINITION Slope-Intercept Equation 0 The equation Figure 1.5 A line with slope mand y-intercept b. y#mx%b is the slope-intercept equationof the line with slope mand y-intercept b. EXAMPLE 4 Writing the Slope-Intercept Equation Write the slope-intercept equation for the line through (!2,!1) and (3,4). SOLUTION The line’s slope is 4!!!1" 5 m#$$#$$#1. 3!!!2" 5 We can use this slope with either of the two given points in the point-slope equation. For (x ,y ) #(!2,!1),we obtain 1 1 y#1•!x!!!2""%!!1" y#x%2%!!1" y#x%1. Now try Exercise 17. If Aand Bare not both zero,the graph of the equation Ax%By#Cis a line. Every line has an equation in this form,even lines with undefined slopes. DEFINITION General Linear Equation The equation Ax%By#C (Aand Bnot both 0) is a general linear equationin xand y.