APEX Answers to Selected Exercises

Appendix A Answers to Selected Exercises

1 Limits
1.1 An Introduction To Limits
1.1.3 Exercises

$-0.1$

Answer 2.

$-7$

Answer 3.

$-0.01$

Answer 4.

$-7$

Answer 5.

$0.01$

Answer 6.

$-7$

Answer 7.

$0.1$

Answer 8.

$-7$

Answer 9.

$-7$

1.1.3.23.

Answer 1.

$-0.1$

Answer 2.

$4.9$

Answer 3.

$-0.01$

Answer 4.

$4.99$

Answer 5.

$0.01$

Answer 6.

$5.01$

Answer 7.

$0.1$

Answer 8.

$5.1$

Answer 9.

$5$

1.1.3.25.

Answer 1.

$-0.1$

Answer 2.

$29.4$

Answer 3.

$-0.01$

Answer 4.

$29.04$

Answer 5.

$0.01$

Answer 6.

$28.96$

Answer 7.

$0.1$

Answer 8.

$28.6$

Answer 9.

$29$

1.1.3.27.

Answer 1.

$-0.1$

Answer 2.

$-0.998334$

Answer 3.

$-0.01$

Answer 4.

$-0.999983$

Answer 5.

$0.01$

Answer 6.

$-0.999983$

Answer 7.

$0.1$

Answer 8.

$-0.998334$

Answer 9.

$-1$

1.3 Finding Limits Analytically

Exercises

$1$

1.4 One-Sided Limits

Exercises

Problems

1.4.5.

1.4.5.a

Answer.

$4$

1.4.5.b

Answer.

$4$

1.4.5.c

Answer.

$4$

1.4.5.d

Answer.

$1$

1.4.5.e

Answer.

$0$

1.4.5.f

Answer.

$\text{DNE}$

1.4.7.

1.4.7.a

Answer.

$\text{DNE}\hbox{ or }\infty $

1.4.7.b

Answer.

$\text{DNE}\hbox{ or }\infty $

1.4.7.c

Answer.

$\text{DNE}\hbox{ or }\infty $

1.4.7.d

Answer.

$\text{DNE}$

1.4.7.e

Answer.

$\text{DNE}$

1.4.7.f

Answer.

$\text{DNE}$

1.4.9.

1.4.9.a

Answer.

$3$

1.4.9.b

Answer.

$3$

1.4.9.c

Answer.

$3$

1.4.9.d

Answer.

$3$

1.4.11.

1.4.11.a

Answer.

$2$

1.4.11.b

Answer.

$2$

1.4.11.c

Answer.

$2$

1.4.11.d

Answer.

$0$

1.4.11.e

Answer.

$2$

1.4.11.f

Answer.

$2$

1.4.11.g

Answer.

$2$

1.4.11.h

Answer.

$\text{DNE}$

1.4.13.

1.4.13.a

Answer.

$3$

1.4.13.b

Answer.

$2$

1.4.13.c

Answer.

$\text{DNE}$

1.4.13.d

Answer.

$3$

1.4.15.

1.4.15.a

Answer.

$-63$

1.4.15.b

Answer.

$-63$

1.4.15.c

Answer.

$-63$

1.4.15.d

Answer.

$-63$

1.4.15.e

Answer.

$9$

1.4.15.f

Answer.

$9$

1.4.15.g

Answer.

$9$

1.4.15.h

Answer.

$9$

1.4.17.

1.4.17.a

Answer.

$1-\cos^{2}\mathopen{}\left(a\right)$

1.4.17.b

Answer.

$\sin^{2}\mathopen{}\left(a\right)$

1.4.17.c

Answer.

$1-\cos^{2}\mathopen{}\left(a\right)\hbox{ or }\sin^{2}\mathopen{}\left(a\right)$

1.4.17.d

Answer.

$\sin^{2}\mathopen{}\left(a\right)$

1.4.19.

1.4.19.a

Answer.

$-2$

1.4.19.b

Answer.

$-2$

1.4.19.c

Answer.

$-2$

1.4.19.d

Answer.

$-5$

1.4.21.

1.4.21.a

Answer.

$-1$

1.4.21.b

Answer.

$1$

1.4.21.c

Answer.

$\text{DNE}$

1.4.21.d

Answer.

$0$

1.5 Continuity

Exercises

Problems

1.5.11.

Answer.

$\text{No.}$

1.5.13.

$\left[1,1.25\right]$

Answer 3.

$\text{+}$

Answer 4.

$\left[1.125,1.25\right]$

Answer 5.

$\text{+}$

Answer 6.

$\left[1.1875,1.25\right]$

Answer 7.

$\text{+}$

Answer 8.

$\left[1.21875,1.25\right]$

Answer 9.

$\text{+}$

Answer 10.

$\left[1.23438,1.25\right]$

Answer 11.

$\text{-}$

Answer 12.

$\left[1.23438,1.24219\right]$

Answer 13.

$\text{-}$

Answer 14.

$\left[1.23438,1.23828\right]$

Answer 15.

$1.23633$

1.5.41.

Answer 1.

$\text{+}$

Answer 2.

$\left[0.675,0.7\right]$

Answer 3.

$\text{+}$

Answer 4.

$\left[0.6875,0.7\right]$

Answer 5.

$\text{-}$

Answer 6.

$\left[0.6875,0.69375\right]$

Answer 7.

$\text{+}$

Answer 8.

$\left[0.690625,0.69375\right]$

Answer 9.

$\text{+}$

Answer 10.

$\left[0.692187,0.69375\right]$

Answer 11.

$\text{+}$

Answer 12.

$\left[0.692969,0.69375\right]$

Answer 13.

$\text{-}$

Answer 14.

$\left[0.692969,0.693359\right]$

Answer 15.

$0.693164$

1.6 Limits Involving Infinity
1.6.4 Exercises

Problems

1.6.4.9.

1.6.4.9.a

Answer.

$\infty $

1.6.4.9.b

Answer.

$\infty $

1.6.4.11.

1.6.4.11.a

Answer.

$0$

1.6.4.11.b

Answer.

$4$

1.6.4.11.c

Answer.

$2$

1.6.4.11.d

Problems

2.1.3.7.

Answer.

$0$

2.1.3.9.

Answer.

$-3$

2.1.3.11.

Answer.

Answer.

$2.9x+y = -1.9$

2.1.3.25.

Answer.

$y-7.77114x = -8.15322$

2.1.3.27.

2.1.3.27.a

Answer.

$-2, 0, 4$

2.1.3.27.b

Answer.

$2x$

2.1.3.27.c

Answer.

$-2, 0, 4$

2.1.3.33.

Answer 1.

$\left(-2,0\right)\cup \left(2,\infty \right)$

Answer 2.

$\left(-\infty ,-2\right)\cup \left(0,2\right)$

Answer 3.

$\left\{-2,0,2\right\}$

Answer 4.

$\left(-1,1\right)$

Answer 5.

$\left(-\infty ,-1\right)\cup \left(1,\infty \right)$

Answer 6.

$\left\{-1,1\right\}$

2.2 Interpretations of the Derivative
2.2.5 Exercises

$\text{g is the derivative of f.}$

2.3 Basic Differentiation Rules
2.3.3 Exercises

Terms and Concepts

2.3.3.3.

Answer.

$e^{x}$

2.3.3.7.

Answer.

$17x-205$

2.3.3.9.

Answer 1.

$\text{a velocity function}$

Answer 2.

Answer.

$8x+4$

2.3.3.27.

Answer 1.

$5x^{4}$

Answer 2.

$20x^{3}$

Answer 3.

$60x^{2}$

Answer 4.

$120x$

2.3.3.29.

Answer 1.

$-\left(2t+3+e^{t}\right)$

Answer 2.

$-\left(2+e^{t}\right)$

Answer 3.

$-e^{t}$

Answer 4.

$-e^{t}$

2.3.3.31.

Answer 1.

$\cos\mathopen{}\left(\theta\right)+\sin\mathopen{}\left(\theta\right)$

Answer 2.

$\cos\mathopen{}\left(\theta\right)-\sin\mathopen{}\left(\theta\right)$

Answer 3.

$-\left(\sin\mathopen{}\left(\theta\right)+\cos\mathopen{}\left(\theta\right)\right)$

Answer 4.

$-\left(\cos\mathopen{}\left(\theta\right)-\sin\mathopen{}\left(\theta\right)\right)$

2.3.3.33.

Answer 1.

$y = 17\mathopen{}\left(x-2\right)+18$

Answer 2.

$y = -{\frac{1}{17}}\mathopen{}\left(x-2\right)+18$

2.3.3.35.

Answer 1.

$y = x-1$

Answer 2.

$y = -\left(x-1\right)$

2.3.3.37.

Answer 1.

$y = \frac{3\sqrt{3}}{2}\mathopen{}\left(x-\frac{\pi }{3}\right)+\frac{-3\cdot 1}{2}$

Answer 2.

$y = -\left({\frac{1}{3}}\frac{2\sqrt{3}}{3}\right)\mathopen{}\left(x-\frac{\pi }{3}\right)+\frac{-3\cdot 1}{2}$

2.4 The Product and Quotient Rules

Exercises

$y = -\left(5x+5\right)$

Answer 2.

$y = \left({\frac{1}{5}}\right)x-5$

2.4.39.

Answer 1.

$y = 64-80\mathopen{}\left(x+8\right)$

Answer 2.

$y = \left({\frac{1}{80}}\right)\mathopen{}\left(x+8\right)+64$

2.4.41.

Answer.

$y = 0$

Answer 2.

$x = 0$

2.5.39.

Answer 1.

$y = -3\mathopen{}\left(x-\frac{\pi }{2}\right)+1$

Answer 2.

$y = \frac{1}{3}\mathopen{}\left(x-\frac{\pi }{2}\right)+1$

2.5.41.

Answer.

$\frac{1}{x}$

2.6 Implicit Differentiation
2.6.4 Exercises

Answer.

$y = 0$

2.6.4.27.b

Answer.

$y = -1.859\mathopen{}\left(x-0.1\right)+0.2811$

2.6.4.29.

2.6.4.29.a

Answer.

$y = 4$

2.6.4.29.b

Answer.

$y = \frac{3}{108^{\frac{1}{4}}}\mathopen{}\left(x-2\right)-108^{\frac{1}{4}}$

2.6.4.31.

2.6.4.31.a

Answer.

$y = \frac{-1}{\sqrt{3}}\mathopen{}\left(x-\frac{7}{2}\right)+\frac{6+3\sqrt{3}}{2}$

2.6.4.31.b

Answer.

$y = \frac{\sqrt{3}\mathopen{}\left(x-\left(4+3\sqrt{3}\right)\right)}{2}+\frac{3}{2}$

2.6.4.33.

Answer.

$\frac{-\left(\left(2y+1\right)\cdot 12x^{2}-4x^{3}\frac{2\mathopen{}\left(-\left(4x^{3}\right)\right)}{2y+1}\right)}{\left(2y+1\right)^{2}}$

2.6.4.35.

Answer.

$\sin^{2}\mathopen{}\left(x\right)\sec^{2}\mathopen{}\left(y\right)\tan\mathopen{}\left(y\right)+\cos\mathopen{}\left(x\right)\sec\mathopen{}\left(y\right)$

2.6.4.37.

Answer 1.

$\left(1+x\right)^{\frac{1}{x}}\mathopen{}\left(\frac{1}{x\mathopen{}\left(x+1\right)}-\frac{\ln\mathopen{}\left(1+x\right)}{x^{2}}\right)$

Answer 2.

$y = \left(1-2\ln\mathopen{}\left(2\right)\right)\mathopen{}\left(x-1\right)+2$

2.6.4.39.

Answer 1.

$\frac{x^{x}}{x+1}\mathopen{}\left(\ln\mathopen{}\left(x\right)+1-\frac{1}{x+1}\right)$

Answer 2.

$y = \frac{1}{4}\mathopen{}\left(x-1\right)+\frac{1}{2}$

2.6.4.41.

Answer 1.

$\frac{x+1}{x+2}\mathopen{}\left(\frac{1}{x+1}-\frac{1}{x+2}\right)$

Answer 2.

$y = \frac{1}{9}\mathopen{}\left(x-1\right)+\frac{2}{3}$

2.7 Derivatives of Inverse Functions

Exercises

$\csc\mathopen{}\left(\frac{1}{x^{2}}\right)\cot\mathopen{}\left(\frac{1}{x^{2}}\right)\frac{2x}{\left(x^{2}\right)^{2}}$

2.7.29.

Answer.

$y = \frac{2\sqrt{3}}{3}\mathopen{}\left(x-{\frac{1}{2}}\right)+\frac{\pi }{6}$

3 The Graphical Behavior of Functions
3.1 Extreme Values

Exercises

Problems

3.1.7.

Answer 1.

$\text{B}$

Answer 2.

$\text{NONE}$

Answer 3.

$\text{B}, \text{G}$

Answer 4.

Exercises

$-\sec^{-1}\mathopen{}\left(\frac{2}{\sqrt{\pi }}\right), \sec^{-1}\mathopen{}\left(\frac{2}{\sqrt{\pi }}\right)$

3.2.19.

Answer.

$5+7\frac{\sqrt{7}}{6}, 5-7\frac{\sqrt{7}}{6}$

3.3 Increasing and Decreasing Functions

Exercises

Terms and Concepts

3.3.3.

$-2.35619, 0.785398$

Answer 6.

$-0.785398, 2.35619$

3.4 Concavity and the Second Derivative
3.4.3 Exercises

$2.35619$

3.4.3.55.

Answer 1.

$\text{NONE}$

Answer 2.

$0.22313$

4 Applications of the Derivative
4.1 Newton’s Method

Exercises

$1$

4.1.9.

Answer.

$\left\{-5.15633,-0.369102,0.525428\right\}$

4.1.11.

Answer.

$\left\{-1.0134,0.988312,1.39341\right\}$

4.1.13.

Answer.

$\left\{-0.824132,0.824132\right\}$

4.1.15.

Answer.

$\left\{0\right\}$

4.2 Related Rates

Exercises

Problems

4.3 Optimization

Exercises

Problems

4.3.3.

Answer.

$2916$

4.3.5.

Answer.

$\text{DNE}$

4.3.7.

Answer.

$16$

4.3.9.

Answer 1.

$3.83722\ {\rm cm}$

Answer 2.

$7.67443\ {\rm cm}$

4.3.11.

Answer 1.

$3.0456\ {\rm cm}$

Answer 2.

$12.1824\ {\rm cm}$

4.3.13.

Answer.

$8.66025\ {\rm in};\,12.2475\ {\rm in}$

4.3.15.

Answer 1.

$0\ {\rm mi}$

Answer 2.

$\$400{,}000$

4.3.17.

Answer.

$11.5311\ {\rm ft}$

4.4 Differentials

Exercises

$4.71239$

4.4.35.

4.4.35.a

Answer.

$297.717\ {\rm ft}$

4.4.35.b

Answer.

$62.3155\ {\rm ft}$

4.4.35.c

Answer.

$20.9\%$

4.4.37.

4.4.37.a

Answer.

$298.868\ {\rm ft}$

4.4.37.b

Answer.

$8.66751\ {\rm ft}$

4.4.37.c

Answer.

$2.9\%$

4.4.39.

Answer.

$1\%$

5 Integration
5.1 Antiderivatives and Indefinite Integration

Exercises

$8e^{x}-4x-12$

5.1.39.

Answer.

$\frac{x^{6}}{3}+\frac{3^{x}}{1.20695}-\cos\mathopen{}\left(x\right)-2.91024x+9.17146$

5.2 The Definite Integral

Exercises

Problems

5.2.5.

5.2.5.a

Answer.

$3$

5.2.5.b

Answer.

$4$

5.2.5.c

Answer.

$3$

5.2.5.d

Answer.

$0$

5.2.5.e

Answer.

$-4$

5.2.5.f

Answer.

$9$

5.2.7.

5.2.7.a

Answer.

$4$

5.2.7.b

Answer.

$2$

5.2.7.c

Answer.

$4$

5.2.7.d

Answer.

$2$

5.2.7.e

Answer.

$1$

5.2.7.f

Answer.

$2$

5.2.9.

5.2.9.a

Answer.

$\pi $

5.2.9.b

Answer.

$\pi $

5.2.9.c

Answer.

$2\pi $

5.2.9.d

Answer.

$10\pi $

5.2.11.

5.2.11.a

Answer.

$-59$

5.2.11.b

Answer.

$-48$

5.2.11.c

Answer.

$-27$

5.2.11.d

Answer.

$-33$

5.2.13.

5.2.13.a

Answer.

$4$

5.2.13.b

Answer.

$4$

5.2.13.c

Answer.

$-4$

5.2.13.d

Answer.

$-2$

5.2.15.

5.2.15.a

Answer.

$2\ {\textstyle\frac{\rm\mathstrut ft}{\rm\mathstrut s}}$

5.2.15.b

Answer.

$2\ {\rm ft}$

5.2.15.c

Answer.

$1.5\ {\rm ft}$

5.2.17.

5.2.17.a

Answer.

$64\ {\textstyle\frac{\rm\mathstrut ft}{\rm\mathstrut s}}$

5.2.17.b

Answer.

$64\ {\rm ft}$

5.2.17.c

Answer.

$2\ {\rm s}$

5.2.17.d

Answer.

$4.64575\ {\rm s}$

5.2.19.

Answer.

$2$

5.2.21.

Answer.

$16$

5.2.23.

Answer.

$22$

5.2.25.

Answer.

$0$

5.3 Riemann Sums
5.3.4 Exercises

Terms and Concepts

5.3.4.3.

$\frac{\left(n+1\right)^{2}}{4n^{2}}$

Answer 2.

$0.3025$

Answer 3.

$0.255025$

Answer 4.

$0.2505$

Answer 5.

${\frac{1}{4}}$

5.3.4.37.

Answer 1.

${\frac{65}{2}}$

Answer 2.

${\frac{65}{2}}$

Answer 3.

${\frac{65}{2}}$

Answer 4.

${\frac{65}{2}}$

Answer 5.

${\frac{65}{2}}$

5.3.4.39.

Answer 1.

$168+\frac{288}{n}$

Answer 2.

$196.8$

Answer 3.

$170.88$

Answer 4.

$168.288$

Answer 5.

$168$

5.4 The Fundamental Theorem of Calculus
5.4.6 Exercises

$2x\mathopen{}\left(x^{2}-1\right)-\left(x-1\right)$

5.4.6.59.

Answer.

$3x^{2}\sin\mathopen{}\left(3x^{6}\right)$

5.5 Numerical Integration
5.5.6 Exercises

$62$

5.5.6.25.

Answer 1.

$30.8667\ {\rm cm^{2}}$

Answer 2.

$308667\ {\rm ft^{2}}$

6 Techniques of Antidifferentiation
6.1 Substitution
6.1.5 Exercises

$\frac{\pi }{2}$

6.2 Integration by Parts

Exercises

$\left(-{\frac{5}{4}}\right)e^{-4}-\left(-{\frac{3}{4}}\right)e^{-2}$

6.2.49.

Answer.

$0.4\mathopen{}\left(-e^{2\pi }+e^{-2\pi }\right)$

6.3 Trigonometric Integrals
6.3.4 Exercises

${\frac{1}{4}}$

6.3.4.33.

Answer.

${\frac{2}{5}}$

6.4 Trigonometric Substitution

Exercises

Terms and Concepts

6.4.3.

Answer 1.

$\tan^{2}\mathopen{}\left(\theta\right)+1 = \sec^{2}\mathopen{}\left(\theta\right)$

Answer 2.

Answer.

$9\sin^{-1}\mathopen{}\left(\left({\frac{1}{3}}\right)\right)+2\sqrt{2}$

6.5 Partial Fraction Decomposition

Exercises

Terms and Concepts

6.5.3.

Answer.

$\frac{A}{x}+\frac{B}{x-5}$

6.5.5.

Answer.

Answer.

$\ln\mathopen{}\left(\left({\frac{5}{3}}\right)\right)+\tan^{-1}\mathopen{}\left(5\right)-\tan^{-1}\mathopen{}\left(3\right)$

6.6 Hyperbolic Functions
6.6.3 Exercises

$0$

6.6.3.47.

Answer.

$0.761594$

6.7 L’Hospital’s Rule
6.7.4 Exercises

$2$

6.7.4.51.

Answer.

$-\infty $

6.7.4.53.

Answer.

$0$

6.8 Improper Integration
6.8.4 Exercises

$\text{Direct Comparison Test}$

Answer 2.

$\text{converges}$

Answer 3.

$\frac{1}{e^{x}}$

7 Applications of Integration
7.1 Area Between Curves

Exercises

$262800\ {\rm ft^{2}}$

7.2 Volume by Cross-Sectional Area; Disk and Washer Methods

Exercises

$250\pi/3$

7.2.21.

Answer.

$187.5$

7.3 The Shell Method

Exercises

$2\pi(1-\sqrt{2}+\sinh^{-1}(1))$

7.4 Arc Length and Surface Area
7.4.3 Exercises

$2\pi\int_0^1 \sqrt{1-x^2}\sqrt{1+x/(1-x^2)}\, dx = 4\pi$

7.5 Work
7.5.4 Exercises

7.5.4.7.b

Answer.

75 %

7.5.4.7.c

Answer.

Answer.

Answer.

4,917,150 J

7.6 Fluid Forces

Exercises

2340 lb
5625 lb

7.6.15.

Answer.

1597.44 lb
3840 lb

7.6.17.

Answer.

56.42 lb
135.62 lb

7.6.19.

Answer.

5.1 ft

8 Differential Equations
8.1 Graphical and Numerical Solutions to Differential Equations
8.1.4 Exercises

Terms and Concepts

8.1.4.1.

Answer.

An initial value problems is a differential equation that is paired with one or more initial conditions. A differential equation is simply the equation without the initial conditions.

8.1.4.3.

Answer.

Substitute the proposed function into the differential equation, and show the the statement is satisfied.

8.1.4.5.

Answer.

Many differential equations are impossible to solve analytically.

Problems

8.1.4.13.

Answer.

$Graph showing slope field for the given differential equation.$

The $x$ and $y$ axes are uncalibrated.In the first quadrant in the top left, the field lines are north-east facing and in the bottom right they are southeast facing. In the second quadrant the field lines are all north-east facing. In the third quadrant like in the first quadrant in the top left the field lines are northeast facing and in the bottom right they are southeast facing. In the fourth quadrant all lines are southeast facing.

8.1.4.15.

Answer.

$Graph showing slope field for the given differential equation.$

The $x$ and $y$ axes are uncalibrated. There are five instances where the field lines run parallel to the $x$ axis. One of them is on the $x$ axis itself, other two pairs of such field lines are above and below the $x$ axis. In between the $x$ axis and the first horizontal field line for some positive $y$ value, the field lines are all northeast facing. Above the horizontal field line for some $y$ value until another with a higher $y$ value, the field lines in between are southeast facing.

Similarly below the $x$ axis till the first horizontal line with some negative $y$ value, the field lines in between are southeast facing. In between this horizontal line and another horizontal line with a higher negative $y$ value, the field lines are northeast facing.

8.1.4.19.

Answer.

$Graph showing slope field for the given differential equation.$

The $x$ and $y$ axes are uncalibrated, the field lines in the first quadrant are shown. Front left to right, a little away from the x axis the field lines are northeast facing that transition to north facing. Moving further right then again become northeast facing then transition to southeast facing, further right they become south facing then east facing. The pattern then repeats. Very close to the $x$ axis the field lines are almost parallel to it.

A wave is drawn that starts at some y intercept above the origin. It has a high positive slope, it reaches peak when the field lines change from northeast facing to southeast facing, then it declines until the point the field lines are parallel to the $x$ axis. The curve continues to form a second wave.

8.1.4.21.

Answer.

$Graph showing slope field for the given differential equation.$

The $x$ and $y$ axes are uncalibrated, the field lines in the first quadrant are shown. In the top right and the centre the field lines are southeast facing, very close to the $x$ and $y$ axis the field lines are almost parallel to the $x$ axis. A curve is drawn that starts from a $y$ intercept and decreases along the slope lines coming close to the $x$ axis.

8.1.4.23.

Answer.

\begin{align*} x_i \amp \quad \amp \quad \amp y_i \\ 0.0 \amp \quad \amp \quad \amp 1.0000 \\ 0.1 \amp \quad \amp \quad \amp 1.0000 \\ 0.2 \amp \quad \amp \quad \amp 1.0037 \\ 0.3 \amp \quad \amp \quad \amp 1.0110 \\ 0.4 \amp \quad \amp \quad \amp 1.0219 \\ 0.5 \amp \quad \amp \quad \amp 1.0363 \end{align*}

8.1.4.25.

Answer.

\begin{align*} x_i \amp \quad \amp \quad \amp y_i \\ 0.0 \amp \quad \amp \quad \amp 0.0000 \\ 0.5 \amp \quad \amp \quad \amp 0.5000 \\ 1.0 \amp \quad \amp \quad \amp 1.8591 \\ 1.5 \amp \quad \amp \quad \amp 10.5824 \\ 2.0 \amp \quad \amp \quad \amp 88378.1190 \end{align*}

8.1.4.27.

Answer.

$x$	$0.0$	$0.2$	$0.4$	$0.6$	$0.8$	$1.0$
$y(x)$	0.5000	0.5412	0.6806	0.9747	1.5551	2.7183
$h = 0.2$	0.5000	0.5000	0.5816	0.7686	1.1250	1.7885
$h = 0.1$	0.5000	0.5201	0.6282	0.8622	1.3132	2.1788

8.2 Separable Differential Equations
8.2.2 Exercises

$2\tan(2y) = 2x + \sin(2x)$

8.3 First Order Linear Differential Equations
8.3.2 Exercises

linear; $\displaystyle y = \frac{x^3-3x-6}{3(x-1)}$

8.3.2.21.

Answer.

$Graph showing slope field for the given differential equation.$

The $x$ and $y$ axes are uncalibrated, the field lines in the first quadrant are shown. On the bottom right the field lines are facing northeast. On the top left the field lines transition from southeast facing to east facing moving downwards. A curve is shown that almost represents a straight line with a positive slope.

The solution will increase and begin to follow the line $y=x-1\text{.}$

$y = x-1 + e^{-x}$

8.4 Modeling with Differential Equations
8.4.3 Exercises

11.00075 g

9 Sequences and Series
9.1 Sequences

Exercises

monotonically increasing

9.1.37.

Answer.

never monotonic

9.2 Infinite Series
9.2.4 Exercises

9.3.4.9.

Answer.

Converges

9.3.4.11.

Answer.

Converges

9.4 Ratio and Root Tests
9.4.3 Exercises

Terms and Concepts

9.4.3.3.

Answer.

Answer.

Converges

9.5 Alternating Series and Absolute Convergence

10 Curves in the Plane
10.1 Conic Sections
10.1.4 Exercises

Problems

10.1.4.19.

Answer.

$\frac{(x+1)^2}{9}+\frac{(y-2)^2}{4}=1\text{;}$ foci at $(-1\pm\sqrt{5},2)\text{;}$ $e=\sqrt{5}/3$

10.1.4.29.

Answer.

$x^2-\frac{y^2}{3}=1$

10.1.4.31.

Answer.

$\frac{(y-3)^2}{4}-\frac{(x-1)^2}{9}=1$

10.1.4.45.

Answer.

The sound originated from a point approximately 31m to the right of $B$ and 1390m above or below it. (Since the three points are collinear, we cannot distinguish whether the sound originated above/below the line containing the points.)

10.2 Parametric Equations
10.2.4 Exercises

Answer.

$y-2x = 3$

10.2.4.35.

Answer 1.

$\frac{t+11}{6}$

Answer 2.

$\frac{t^{2}-97}{12}$

Answer 3.

$\left(2,-8\right)$

Answer 4.

$6x-11$

Answer 5.

$1$

10.2.4.37.

Answer 1.

$\cos^{-1}\mathopen{}\left(t\right)$

Answer 2.

$\sqrt{1-t^{2}}$

Answer 3.

$\left(0,0\right)$

Answer 4.

$\cos\mathopen{}\left(x\right)$

Answer 5.

$1$

10.2.4.39.

Answer 1.

$-1, 1$

Answer 2.

$\left(3,-2\right)$

10.2.4.51.

Answer.

$3\cos\mathopen{}\left(2\pi t\right)+1;\,3\sin\mathopen{}\left(2\pi t\right)+1$

10.3 Calculus and Parametric Equations
10.3.4 Exercises

$\left(-\infty ,0.5\right]$

Answer 3.

$\left[0.5,\infty \right)$

10.3.4.33.

Answer.

$6\pi $

10.3.4.35.

Answer.

$2\sqrt{34}$

10.4 Introduction to Polar Coordinates
10.4.4 Exercises

Problems

10.4.4.5.

Answer.

$The four points plotted in this exercise.$

On a polar grid, four points are plotted. The point $A$ is at the intersection of the initial ray and the circle of radius 2. Points $B$ and $D$ are both on the circle of radius 1. The point $B$ is on the same line as the initial ray, but in the opposite direction. The point $D$ lies above the initial ray, making an angle of $\pi/4\text{.}$ Finally, the point $C$ is at the bottom of the circle of radius $2\text{.}$

10.4.4.7.

Answer.

$A=P(2.5,\pi/4)$ and $P(-2.5,5\pi/4)\text{;}$

$B=P(-1,5\pi/6)$ and $P(1,11\pi/6)\text{;}$

$C=P(3,4\pi/3)$ and $P(-3,\pi/3)\text{;}$

$D=P(1.5,2\pi/3)$ and $P(-1.5,5\pi/3)\text{;}$

10.4.4.9.

Answer 1.

$\left(\sqrt{2},\sqrt{2}\right)$

Answer 2.

$\left(\sqrt{2},-\sqrt{2}\right)$

Answer.

Answer.

$P\left(0,0\right), P\left(\sqrt{2},\frac{\pi }{4}\right)$

10.5 Calculus and Polar Functions
10.5.5 Exercises

Terms and Concepts

11.1.7.5.

Answer.

A hyperboloid of two sheets

Problems

11.1.7.7.

Answer 1.

$\sqrt{6}$

Answer 2.

$\sqrt{17}$

Answer 3.

$\sqrt{11}$

Answer 4.

$\text{do}$

11.1.7.9.

Answer 1.

$\left(4,-1,0\right)$

Exercises

Terms and Concepts

11.2.9.a

Answer.

$\left<6,-1,6\right>$

11.2.9.b

Answer 1.

$\sqrt{5}$

Answer 2.

$3\sqrt{5}$

Answer 3.

$2\sqrt{5}$

Answer 4.

$4\sqrt{5}$

11.2.23.

Answer.

$\left<0.6,0.8\right>$

11.2.25.

Answer.

$\left<\frac{1}{\sqrt{3}},\frac{-1}{\sqrt{3}},\frac{1}{\sqrt{3}}\right>$

11.2.27.

Answer.

$\left<\frac{-1}{2},\frac{\sqrt{3}}{2}\right>$

11.3 The Dot Product
11.3.2 Exercises

$\frac{\pi }{4}$

11.3.2.17.

Answer 1.

$\left<-7,4\right>$

Answer 2.

$\left<4,7\right>$

11.3.2.19.

Answer 1.

$\left<1,0,-1\right>$

Answer 2.

$\left<1,1,1\right>$

11.3.2.21.

Answer.

$\left<\frac{-5}{10},\frac{15}{10}\right>$

11.3.2.23.

Answer.

$\left<\frac{-1}{2},\frac{-1}{2}\right>$

11.3.2.25.

Answer.

$\left<\frac{14}{14},\frac{28}{14},\frac{42}{14}\right>$

11.3.2.27.

Answer 1.

$\left<\frac{-5}{10},\frac{15}{10}\right>$

Answer 2.

$\left<\frac{15}{10},\frac{5}{10}\right>$

11.3.2.29.

Answer 1.

$\left<\frac{-1}{2},\frac{-1}{2}\right>$

Answer 2.

$\left<\frac{-5}{2},\frac{5}{2}\right>$

11.3.2.31.

Answer 1.

$\left<\frac{14}{14},\frac{28}{14},\frac{42}{14}\right>$

Answer 2.

$\left<\frac{0}{14},\frac{42}{14},\frac{-28}{14}\right>$

11.3.2.33.

Answer.

1.96lb

11.3.2.35.

Answer.

$141.42$ft–lb

11.3.2.37.

Answer.

$500$ft–lb

11.3.2.39.

Answer.

$500$ft–lb

11.4 The Cross Product
11.4.3 Exercises

$200/3\approx 66.67$ft–lb

11.5 Lines
11.5.4 Exercises

Terms and Concepts

11.5.4.1.

Answer.

A point on the line and the direction of the line.

Problems

11.5.4.11.

Answer 1.

$\left(7,2,-1\right)+t\mathopen{}\left<1,-1,2\right>$

Answer 2.

$x = 7+t, y = 2-t, z = -1+2t$

Terms and Concepts

11.6.2.1.

Answer.

A point in the plane and a normal vector (i.e., a direction orthogonal to the plane).

Problems

11.6.2.3.

Answer.

Answers will vary.

11.6.2.5.

Answer.

Answers will vary.

11.6.2.17.

Answer 1.

$x-5+y-7+z-3 = 0$

Answer 2.

$x+y+z = 15$

11.6.2.19.

Answer 1.

$3\mathopen{}\left(x+4\right)+8\mathopen{}\left(y-7\right)-10\mathopen{}\left(z-2\right) = 0$

Answer 2.

$3x+8y-10z = 24$

11.6.2.27.

Answer.

$\sqrt{5/7}$

11.6.2.29.

Answer.

$1/\sqrt{3}$

12 Vector Valued Functions
12.1 Vector-Valued Functions
12.1.4 Exercises

Problems

12.1.4.15.

Answer.

$\vec r(t) = \la 3t+1, 3t+2, 3t+3\ra\text{.}$

12.1.4.29.

Answer.

$\left<2\cos\mathopen{}\left(t\right),2\sin\mathopen{}\left(t\right),2t\right>$

12.1.4.31.

Answer.

$\left<1,0\right>$

12.1.4.33.

Answer.

$\left<0,0,1\right>$

12.2 Calculus and Vector-Valued Functions
12.2.5 Exercises

$\frac{1}{54}\mathopen{}\left(22^{\frac{3}{2}}-8\right)$

12.3 The Calculus of Motion
12.3.3 Exercises

Problems

12.3.3.7.

Answer.

$\vvt = \la 2,5,0\ra\text{,}$ $\vat = \la 0,0,0\ra$

12.3.3.19.

Answer 1.

$\left|\sec\mathopen{}\left(t\right)\right|\sqrt{\tan^{2}\mathopen{}\left(t\right)+\sec^{2}\mathopen{}\left(t\right)}$

Answer 2.

$0$

Answer 3.

$\frac{\pi }{4}$

12.3.3.39.

12.3.3.39.a

Answer.

$0.013\ {\rm radians}$

12.3.3.39.b

Answer.

$11.7\ {\rm ft}$

12.4 Unit Tangent and Normal Vectors
12.4.4 Exercises

Terms and Concepts

12.4.4.3.

Answer.

$\unittangent(t)$ and $\unitnormal(t)\text{.}$

Problems

12.4.4.5.

Answer.

$\unittangent(t) = \la\frac{4 t}{\sqrt{20 t^2-4t+1}},\frac{2 t-1}{\sqrt{20 t^2-4t+1}}\ra\text{;}$ $\unittangent(1) = \la 4/\sqrt{17},1/\sqrt{17}\ra$

12.4.4.9.

Answer.

$\left(2,0\right)+t\mathopen{}\left<\frac{4}{\sqrt{17}},\frac{1}{\sqrt{17}}\right>$

12.4.4.13.

Answer.

$\unittangent(t) = \la -\sin(t) ,\cos(t) \ra\text{;}$ $\unitnormal(t) = \la -\cos(t) ,-\sin(t) \ra$

12.4.4.15.

Answer.

$\unittangent(t) = \la -\frac{\sin(t) }{\sqrt{4\cos^2(t) +\sin^2(t) }},\frac{2\cos(t) }{\sqrt{4\cos^2(t) +\sin^2(t) }}\ra\text{;}$ $\unitnormal(t) = \la -\frac{2\cos(t) }{\sqrt{4\cos^2(t) +\sin^2(t) }},-\frac{\sin(t) }{\sqrt{4\cos^2(t) +\sin^2(t) }}\ra$

12.5 The Arc Length Parameter and Curvature
12.5.4 Exercises

Terms and Concepts

12.5.4.3.

Answer.

Answers may include lines, circles, helixes

12.5.4.5.

Answer.

$\kappa$

Problems

12.5.4.15.

Answer 1.

$\text{less than}$

Answer 2.

$\frac{\left|2\cos\mathopen{}\left(t\right)\cos\mathopen{}\left(2t\right)+4\sin\mathopen{}\left(t\right)\sin\mathopen{}\left(2t\right)\right|}{\left(4\cos^{2}\mathopen{}\left(2t\right)+\sin^{2}\mathopen{}\left(t\right)\right)^{\frac{3}{2}}}$

Answer 3.

$\frac{1}{4}$

Answer 4.

$8$

12.5.4.23.

Answer.

$\frac{\sqrt{2}}{\sqrt[4]{5}}, \frac{-\sqrt{2}}{\sqrt[4]{5}}$

Answer.

Answers will vary. interior point: $(1,3)$ boundary point: $(3,3)$
$S$ is a closed set
$S$ is bounded

13.2.5.11.

Answer.

$D = \left\{(x,y)\, |\, 9-x^2-y^2\geq 0\right\}\text{.}$
$D$ is a closed set.
$D$ is bounded.

13.2.5.13.

Answer.

$D = \left\{(x,y)\, |\, y \gt x^2\right\}\text{.}$
$D$ is an open set.
$D$ is unbounded.

13.3 Partial Derivatives
13.3.7 Exercises

Problems

13.3.7.19.

Answer 1.

$\frac{2y^{2}}{\sqrt{4xy^{2}+1}}$

Answer 2.

$\frac{4xy}{\sqrt{4xy^{2}+1}}$

Answer 3.

$\frac{-4y^{4}}{\left(\sqrt{4xy^{2}+1}\right)^{3}}$

Answer 4.

$\frac{-8xy^{3}}{\left(\sqrt{4xy^{2}+1}\right)^{3}}+\frac{4y}{\sqrt{4xy^{2}+1}}$

Answer 5.

$\frac{-8xy^{3}}{\left(\sqrt{4xy^{2}+1}\right)^{3}}+\frac{4y}{\sqrt{4xy^{2}+1}}$

Answer 6.

$\frac{-16x^{2}y^{2}}{\left(\sqrt{4xy^{2}+1}\right)^{3}}+\frac{4x}{\sqrt{4xy^{2}+1}}$

13.5 The Multivariable Chain Rule
13.5.3 Exercises

Problems

13.5.3.7.

Answer.

$\frac{dz}{dt} = 3(2t)+4(2) = 6t+8\text{.}$
At $t=1\text{,}$ $\frac{dz}{dt} = 14\text{.}$

13.5.3.9.

Answer.

$\displaystyle \frac{dz}{dt} = 5(-2\sin(t) )+2(\cos(t) ) = -10\sin(t) +2\cos(t)$
At $t=\pi/4\text{,}$ $\frac{dz}{dt} = -4\sqrt{2}\text{.}$

13.5.3.11.

Answer.

$\ds\frac{dz}{dt} = 2x(\cos(t) ) + 4y(3\cos(t) )\text{.}$
At $t=\pi/4\text{,}$ $x=\sqrt{2}/2\text{,}$ $y=3\sqrt{2}/2\text{,}$ and $\frac{dz}{dt} = 19\text{.}$

13.5.3.21.

Answer 1.

$2x\cos\mathopen{}\left(t\right)+2y\sin\mathopen{}\left(t\right)$

Answer 2.

$-2xs\sin\mathopen{}\left(t\right)+2ys\cos\mathopen{}\left(t\right)$

Answer 3.

$4$

Answer 4.

$0$

13.6 Directional Derivatives
13.6.3 Exercises

$\sqrt{8}$

13.6.3.19.c

Answer.

$\la 2, -2\ra$

13.6.3.19.d

Answer.

$\vec u = \la 1/\sqrt{2},1/\sqrt{2}\ra$

13.6.3.21.

13.6.3.21.a

Answer.

$\nabla f(1,1) = \la -2/9,-2/9\ra$

13.6.3.21.b

Answer 1.

$3$

Answer 2.

$\left(0,1\right)$

Answer 3.

$\frac{3}{4}$

Answer 4.

$\left(0,\frac{-1}{2}\right)$

14 Multiple Integration
14.1 Iterated Integrals and Area
14.1.4 Exercises

Problems

14.1.4.5.

14.1.4.5.a

Answer.

$18x^2+42x-117$

14.1.4.5.b

Answer.

$-108$

14.1.4.7.

14.1.4.7.a

Answer.

$x^4/2-x^2+2x-3/2$

14.1.4.7.b

14.3.3.

Answer.

$4\pi $

14.3.5.

Answer.

$16\pi $

14.5 Surface Area

Exercises

Problems

14.5.7.

Answer.

$\ds SA = \int_0^{2\pi}\int_0^{2\pi} \sqrt{1+ \cos^2(x) \cos^2(y) +\sin^2(x) \sin^2(y) }\, dx\, dy$

14.5.9.

Answer.

$\ds SA = \int_{-1}^{1}\int_{-1}^{1} \sqrt{1+ 4x^2+4y^2}\, dx\, dy$

14.6 Volume Between Surfaces and Triple Integration
14.6.4 Exercises

Problems

14.6.4.9.

Answer.

$dz\, dy\, dx\text{:}$ $\ds\int_0^3\int_0^{1-x/3}\int_0^{2-2x/3-2y}\, dz\, dy\, dx$

$dz\, dx\, dy\text{:}$ $\ds\int_0^1\int_0^{3-3y}\int_0^{2-2x/3-2y}\, dz\, dx\, dy$

$dy\, dz\, dx\text{:}$ $\ds\int_0^3\int_0^{2-2x/3}\int_0^{1-x/3-z/2}\, dy\, dz\, dx$

$dy\, dx\, dz\text{:}$ $\ds\int_0^2\int_0^{3-3z/2}\int_0^{1-x/3-z/2}\, dy\, dx\, dz$

$dx\, dz\, dy\text{:}$ $\ds\int_0^1\int_0^{2-2y}\int_0^{3-3y-3z/2}\, dx\, dz\, dy$

$dx\, dy\, dz\text{:}$ $\ds\int_0^2\int_0^{1-z/2}\int_0^{3-3y-3z/2}\, dx\, dy\, dz$

$\ds V = \int_0^3\int_0^{1-x/3}\int_0^{2-2x/3-2y}\, dz\, dy\, dx =1\text{.}$

14.6.4.11.

Answer.

$dz\, dy\, dx\text{:}$ $\ds\int_0^2\int_{-2}^{0}\int_{y^2/2}^{-y}\, dz\, dy\, dx$

$dz\, dx\, dy\text{:}$ $\ds\int_{-2}^0\int_0^{2}\int_{y^2/2}^{-y}\, dz\, dx\, dy$

$dy\, dz\, dx\text{:}$ $\ds\int_0^2\int_0^{2}\int_{-\sqrt{2z}}^{-z}\, dy\, dz\, dx$

$dy\, dx\, dz\text{:}$ $\ds\int_0^2\int_0^{2}\int_{-\sqrt{2z}}^{-z}\, dy\, dx\, dz$

$dx\, dz\, dy\text{:}$ $\ds\int_{-2}^0\int_{y^2/2}^{-y}\int_0^{2}\, dx\, dz\, dy$

$dx\, dy\, dz\text{:}$ $\ds\int_0^2\int_{-\sqrt{2z}}^{-z}\int_0^{2}\, dx\, dy\, dz$ $\ds V = \int_0^2\int_0^{2}\int_{-\sqrt{2z}}^{-z}\, dy\, dz\, dx =4/3\text{.}$

14.6.4.13.

Answer.

$dz\, dy\, dx\text{:}$ $\ds\int_0^2\int_{1-x/2}^{1}\int_{0}^{2x+4y-4}\, dz\, dy\, dx$

$dz\, dx\, dy\text{:}$ $\ds\int_{0}^1\int_{2-2y}^{2}\int_{0}^{2x+4y-4}\, dz\, dx\, dy$

$dy\, dz\, dx\text{:}$ $\ds\int_0^2\int_0^{2x}\int_{z/4-x/2+1}^{1}\, dy\, dz\, dx$

$dy\, dx\, dz\text{:}$ $\ds\int_0^4\int_{z/2}^{2}\int_{z/4-x/2+1}^{1}\, dy\, dx\, dz$

$dx\, dz\, dy\text{:}$ $\ds\int_{0}^1\int_{0}^{4y}\int_{z/2-2y+2}^2\, dx\, dz\, dy$

$dx\, dy\, dz\text{:}$ $\ds\int_0^4\int_{z/4}^{1}\int_{z/2-2y+2}^2\, dx\, dy\, dz$ $\ds V = \int_0^4\int_{z/4}^{1}\int_{z/2-2y-2}^2\, dx\, dy\, dz = 4/3\text{.}$

14.6.4.15.

Answer.

$dz\, dy\, dx\text{:}$ $\ds\int_{0}^1\int_{0}^{1-x^2}\int_{0}^{\sqrt{1-y}}\, dz\, dy\, dx$

$dz\, dx\, dy\text{:}$ $\ds\int_{0}^1\int_{0}^{\sqrt{1-y}}\int_{0}^{\sqrt{1-y}}\, dz\, dx\, dy$

$dy\, dz\, dx\text{:}$ $\ds\int_{0}^1\int_0^{x}\int_{0}^{1-x^2}\, dy\, dz\, dx + \int_{0}^1\int_x^{1}\int_{0}^{1-z^2}\, dy\, dz\, dx$

$dy\, dx\, dz\text{:}$ $\ds\int_0^1\int_{0}^{z}\int_{0}^{1-z^2}\, dy\, dx\, dz+\int_0^1\int_{z}^{1}\int_{0}^{1-x^2}\, dy\, dx\, dz$

$dx\, dz\, dy\text{:}$ $\ds\int_{0}^1\int_{0}^{\sqrt{1-y}}\int_{0}^{\sqrt{1-y}}\, dx\, dz\, dy$

$dx\, dy\, dz\text{:}$ $\ds\int_0^1\int_{0}^{1-z^2}\int_{0}^{\sqrt{1-y}}\, dx\, dy\, dz$ Answers will vary. Neither order is particularly “hard.” The order $dz\, dy\, dx$ requires integrating a square root, so powers can be messy; the order $dy\, dz\, dx$ requires two triple integrals, but each uses only polynomials.

14.7 Triple Integration with Cylindrical and Spherical Coordinates
14.7.3 Exercises

Problems

14.7.3.11.

Answer.

$\ds\int_{\theta_1}^{\theta_2}\int_{r_1}^{r_2}\int_{z_1}^{z_2}h(r,\theta,z)r\, dz\, dr\, d\theta$

14.7.3.19.

Answer.

Describes the portion of the unit ball that resides in the first octant.

15 Vector Analysis
15.1 Introduction to Line Integrals
15.1.4 Exercises

Terms and Concepts

15.1.4.1.

Answer.

When $C$ is a curve in the plane and $f$ is a function defined over $C\text{,}$ then $\int_C f(s)\, ds$ describes the area under the spatial curve that lies on $f\text{,}$ over $C\text{.}$

15.1.4.3.

Answer.

Answer.

$M=8\sqrt{2}\pi^2\text{;}$ center of mass is $(0,-1/(2\pi), 8\pi/3)\text{.}$

15.2 Vector Fields
15.2.3 Exercises

Terms and Concepts

15.2.3.1.

Answer.

Answers will vary. Appropriate answers include velocities of moving particles (air, water, etc.); gravitational or electromagnetic forces.

15.3 Line Integrals over Vector Fields
15.3.4 Exercises

Terms and Concepts

15.3.4.5.

Answer.

Answer.

$\displaystyle f(x,y) = xy+x$
$\curl \vec F = 0\text{.}$
$1\text{.}$ (One parametrization for $C$ is $\vec r(t) = \langle t,t-1\rangle$ on $0\leq t\leq 1\text{.}$)
$1$ (with $A = (0,1)$ and $B = (1,0)\text{,}$ $f(B) - f(A) = 1\text{.}$)

15.3.4.19.

Answer.

$\displaystyle f(x,y) = x^2yz$
$\curl \vec F = \vec 0\text{.}$
$250\text{.}$
$250$ (with $A = (1,-1,0)$ and $B = (5,5,2)\text{,}$ $f(B) - f(A) = 250\text{.}$)

15.4 Flow, Flux, Green’s Theorem and the Divergence Theorem
15.4.4 Exercises

Problems

15.4.4.7.

Answer.

$12$

15.4.4.9.

Answer.

$-2/3$

15.4.4.11.

Answer.

$1/2$

15.4.4.13.

Answer.

The line integral $\oint_C\vec F\cdot d\vec r\text{,}$ over the parabola, is $38/3\text{;}$ over the line, it is $-10\text{.}$ The total line integral is thus $38/3-10 = 8/3\text{.}$ The double integral of $\curl \vec F = 2$ over $R$ also has value $8/3\text{.}$

15.4.4.15.

Answer.

Three line integrals need to be computed to compute $\oint_C \vec F\cdot d\vec r\text{.}$ It does not matter which corner one starts from first, but be sure to proceed around the triangle in a counterclockwise fashion.

From $(0,0)$ to $(2,0)\text{,}$ the line integral has a value of 0. From $(2,0)$ to $(1,1)$ the integral has a value of $7/3\text{.}$ From $(1,1)$ to $(0,0)$ the line integral has a value of $-1/3\text{.}$ Total value is 2.

The double integral of $\curl\vec F$ over $R$ also has value 2.

15.4.4.17.

Answer.

Any choice of $\vec F$ is appropriate as long as $\curl \vec F = 1\text{.}$ When $\vec F = \langle -y/2,x/2\rangle\text{,}$ the integrand of the line integral is simply 6. The area of $R$ is $12\pi\text{.}$

15.4.4.19.

Answer.

15.5.3.3.

Answer.

$\vec r(u,v) = \langle u, v, 3u^2v\rangle$ on $-1\leq u\leq 1\text{,}$ $0\leq v\leq 2\text{.}$
$\vec r(u,v) = \langle 3v\cos(u)+1, 3v\sin(u)+2, 3(3v\cos(u)+1)^2(3v\sin(u)+2)\rangle\text{,}$ on $0\leq u\leq 2\pi\text{,}$ $0\leq v\leq 1\text{.}$
$\vec r(u,v) = \langle u, v(2-2u), 3u^2v(2-2u)\rangle$ on $0\leq u, v\leq 1\text{.}$
$\vec r(u,v) = \langle u, v(1-u^2), 3u^2v(1-u^2)\rangle$ on $-1\leq u\leq 1\text{,}$ $0\leq v\leq 1\text{.}$

15.5.3.5.

Answer.

$\vec r(u,v) = \langle 0, u, v\rangle$ with $0\leq u\leq 2\text{,}$ $0\leq v\leq 1\text{.}$

15.5.3.7.

Answer.

$\vec r(u,v) = \langle 3\sin(u)\cos(v), 2\sin(u)\sin(v), 4\cos(u)\rangle$ with $0\leq u\leq \pi\text{,}$ $0\leq v\leq 2\pi\text{.}$

15.5.3.9.

Answer.

Answers may vary.

For $z = \frac12(3-x)\text{:}$ $\vec r(u,v) = \langle u, v , \frac12(3-u)\rangle\text{,}$ with $1\leq u\leq 3$ and $0\leq v\leq 2\text{.}$

For $x=1\text{:}$ $\vec r(u,v) = \langle 1,u,v\rangle\text{,}$ with $0\leq u\leq 2\text{,}$ $0\leq v\leq 1$

For $y=0\text{:}$ $\vec r(u,v) = \langle u,0,v/2(3-u)\rangle\text{,}$ with $1\leq u\leq 3\text{,}$ $0\leq v\leq 1$

For $y=2\text{:}$ $\vec r(u,v) = \langle u,2,v/2(3-u)\rangle\text{,}$ with $1\leq u\leq 3\text{,}$ $0\leq v\leq 1$

For $z=0\text{:}$ $\vec r(u,v) = \langle u,v,0\rangle\text{,}$ with $1\leq u\leq 3\text{,}$ $0\leq v\leq 2$

15.5.3.11.

Answer.

Answers may vary.

For $z=2y: \vec r(u,v) = \langle u, v(4-u^2), 2v(4-u^2)\rangle$ with $-2\leq u\leq 2$ and $0\leq v\leq 1\text{.}$

For $y=4-x^2: \vec r(u,v) = \langle u, 4-u^2, 2v(4-u^2)\rangle$ with $-2\leq u\leq 2$ and $0\leq v\leq 1\text{.}$

For $z=0\text{:}$ $\vec r(u,v) = \langle u, v(4-u^2), 0\rangle$ with $-2\leq u\leq 2$ and $0\leq v\leq 1\text{.}$

15.5.3.13.

Answer.

Answers may vary.

For $x^2+y^2/9=1\text{:}$ $\vec r(u,v) = \langle \cos(u), 3\sin(u), v\rangle$ with $0\leq u\leq 2\pi$ and $1\leq v\leq 3\text{.}$

For $z=1\text{:}$ $\vec r(u,v) = \langle v\cos(u), 3v\sin(u), 1\rangle$ with $0\leq u\leq 2\pi$ and $0\leq v\leq 1\text{.}$

For $z=3\text{:}$ $\vec r(u,v) = \langle v\cos(u), 3v\sin(u), 3\rangle$ with $0\leq u\leq 2\pi$ and $0\leq v\leq 1\text{.}$

15.5.3.15.

Answer.

Answers may vary.

For $z=1-x^2\text{:}$ $\vec r(u,v) = \langle u,v,1-u^2\rangle$ with $-1\leq u\leq 1$ and $-1\leq v\leq 2\text{.}$

For $y=-1\text{:}$ $\vec r(u,v) = \langle u,-1,v(1-u^2)\rangle$ with $-1\leq u\leq 1$ and $0\leq v\leq 1\text{.}$

For $y=2\text{:}$ $\vec r(u,v) = \langle u,2,v(1-u^2)\rangle$ with $-1\leq u\leq 1$ and $0\leq v\leq 1\text{.}$

For $z=0\text{:}$ $\vec r(u,v) = \langle u,v,0\rangle$ with $-1\leq u\leq 1$ and $-1\leq v\leq 2\text{.}$

15.5.3.17.

Answer.

$S = 2\sqrt{14}\text{.}$

15.5.3.19.

Answer.

$S = 4\sqrt{3}\pi\text{.}$

15.5.3.21.

Answer.

$S =\int_0^3\int_0^{2\pi}\sqrt{v^2+4v^4}\, du\, dv= (37\sqrt{37}-1)\pi/6 \approx 117.319\text{.}$

15.5.3.23.

Answer.

$S =\int_0^1\int_{-1}^{1}\sqrt{(5u^2-5)^2+2(1-u^2)^2}\, du\, dv = 4\sqrt{3}\approx 6.9282\text{.}$

15.6 Surface Integrals
15.6.3 Exercises

Problems

15.6.3.5.

Answer.

$240\sqrt{3}$

15.6.3.7.

Answer.

$24$

15.6.3.9.

Answer.

$0$

15.6.3.11.

Answer.

$-1/2$

15.6.3.13.

Answer.

$0\text{;}$ the flux over $\surfaceS_1$ is $-45\pi$ and the flux over $\surfaceS_2$ is $45\pi\text{.}$

15.7 The Divergence Theorem and Stokes’ Theorem
15.7.4 Exercises

Terms and Concepts

15.7.4.1.

Answer.

Answers will vary; in Section 15.4, the Divergence Theorem connects outward flux over a closed curve in the plane to the divergence of the vector field, whereas in this section the Divergence Theorem connects outward flux over a closed surface in space to the divergence of the vector field.

15.7.4.3.

Answers will vary. Often the closed surface $\surfaceS$ is composed of several smooth surfaces. To measure total outward flux, this may require evaluating multiple double integrals. Each double integral requires the parametrization of a surface and the computation of the cross product of partial derivatives. One triple integral may require less work, especially as the divergence of a vector field is generally easy to compute.

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\(x\)	\(0.0\)	\(0.2\)	\(0.4\)	\(0.6\)	\(0.8\)	\(1.0\)
\(y(x)\)	0.5000	0.5412	0.6806	0.9747	1.5551	2.7183
\(h = 0.2\)	0.5000	0.5000	0.5816	0.7686	1.1250	1.7885
\(h = 0.1\)	0.5000	0.5201	0.6282	0.8622	1.3132	2.1788

Appendix A Answers to Selected Exercises

1 Limits1.1 An Introduction To Limits1.1.3 Exercises

Problems

1.1.3.7.

1.1.3.9.

1.1.3.11.

1.1.3.13.

1.1.3.15.

1.1.3.17.

1.1.3.19.

1.1.3.21.

1.1.3.23.

1.1.3.25.

1.1.3.27.

1.3 Finding Limits Analytically

Exercises

Problems

1.3.7.

1.3.9.

1.3.11.

1.3.13.

1.3.15.

1.3.17.

1.3.19.

1.3.21.

1.3.23.

1.3.25.

1.3.27.

1.3.29.

1.3.31.

1.3.33.

1.3.35.

1.3.37.

1.3.39.

1.3.41.

1.4 One-Sided Limits

Exercises

Problems

1.4.5.

1.4.7.

1.4.9.

1.4.11.

1.4.13.

1.4.15.

1.4.17.

1.4.19.

1.4.21.

1.5 Continuity

Exercises

Problems

1.5.11.

1.5.13.

1.5.15.

1.5.17.

1.5.19.

1.5.21.

1.5.23.

1.5.25.

1.5.27.

1.5.29.

1.5.31.

1.5.33.

1.5.39.

1.5.41.

1.6 Limits Involving Infinity1.6.4 Exercises

Problems

1.6.4.9.

1.6.4.11.

1.6.4.13.

1.6.4.15.

1.6.4.17.

1.6.4.19.

1.6.4.21.

1.6.4.23.

1.6.4.25.

1.6.4.27.

2 Derivatives2.1 Instantaneous Rates of Change: The Derivative2.1.3 Exercises

Problems

2.1.3.7.

2.1.3.9.

1 Limits
1.1 An Introduction To Limits
1.1.3 Exercises

1.6 Limits Involving Infinity
1.6.4 Exercises

2 Derivatives
2.1 Instantaneous Rates of Change: The Derivative
2.1.3 Exercises

2.2 Interpretations of the Derivative
2.2.5 Exercises

2.3 Basic Differentiation Rules
2.3.3 Exercises