Consider two athletes running at variable speeds \(v_{1}(t)\) and \(v_{2}(t)\). The runners start and finish a race at exactly the same time. Explain why the two runners must be going the same speed at some point. Text Transcription: v_1(t) v_2(t)
Read more- Calculus / Calculus Volume 1 18 / Chapter 5.3 / Problem 192
Table of Contents
Textbook Solutions for Calculus Volume 1
Question
In the following exercises, use the evaluation theorem to express the integral as a function F(x).
\(\int_{0}^{x} \cos t d t\)
Text Transcription:
int_0^x cos tdt
Solution
The first step in solving 5.3 problem number trying to solve the problem we have to refer to the textbook question: In the following exercises, use the evaluation theorem to express the integral as a function F(x).\(\int_{0}^{x} \cos t d t\)Text Transcription:int_0^x cos tdt
From the textbook chapter The Fundamental Theorem of Calculus you will find a few key concepts needed to solve this.
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full solution
Solved: ?In the following exercises, use the evaluation theorem to express the integral
Chapter 5.3 textbook questions
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Chapter 5: Problem 144 Calculus Volume 1 18 -
Chapter 5: Problem 145 Calculus Volume 1 18Two mountain climbers start their climb at base camp, taking two different routes, one steeper than the other, and arrive at the peak at exactly the same time. Is it necessarily true that, at some point, both climbers increased in altitude at the same rate?
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Chapter 5: Problem 146 Calculus Volume 1 18To get on a certain toll road a driver has to take a card that lists the mile entrance point. The card also has a timestamp. When going to pay the toll at the exit, the driver is surprised to receive a speeding ticket along with the toll. Explain how this can happen.
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Chapter 5: Problem 147 Calculus Volume 1 18Set \(F(x)=\int_{1}^{x}(1-t) d t\). Find \(F^{\prime}(2)\) and the average value of \(F^{\prime}\) over [1,2]. Text Transcription: F(x)=int_1^x (1-t) dt F^prime(2) F^prime
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Chapter 5: Problem 148 Calculus Volume 1 18In the following exercises, use the Fundamental Theorem of Calculus, Part 1, to find each derivative. \(\frac{d}{d x} \int_{1}^{x} e^{-t^{2}} d t\) Text Transcription: d/dx int_1^x e^-t^2 dt
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Chapter 5: Problem 149 Calculus Volume 1 18In the following exercises, use the Fundamental Theorem of Calculus, Part 1, to find each derivative. \(\frac{d}{d x} \int_{1}^{x} e^{\cos t} d t\) Text Transcription: d/dx int_1^x e^cos t dt
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Chapter 5: Problem 150 Calculus Volume 1 18In the following exercises, use the Fundamental Theorem of Calculus, Part 1, to find each derivative. \(\frac{d}{d x} \int_{3}^{x} \sqrt{9-y^{2}} d y\) Text Transcription: d/dx int_3^x sqrt 9-y^2 dy
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Chapter 5: Problem 151 Calculus Volume 1 18In the following exercises, use the Fundamental Theorem of Calculus, Part 1, to find each derivative. \(\frac{d}{d x} \int_{4}^{x} \frac{d s}{\sqrt{16-s^{2}}}\) Text Transcription: d/dx int_4^x ds/sqrt 16-s^2
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Chapter 5: Problem 152 Calculus Volume 1 18In the following exercises, use the Fundamental Theorem of Calculus, Part 1, to find each derivative. \(\frac{d}{d x} \int_{x}^{2 x} t d t\) Text Transcription: d/dx int_x^2x tdt
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Chapter 5: Problem 153 Calculus Volume 1 18In the following exercises, use the Fundamental Theorem of Calculus, Part 1, to find each derivative. \(\frac{d}{d x} \int_{0}^{\sqrt{x}} t d t\) Text Transcription: d/dx int_0^sqrt x tdt
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Chapter 5: Problem 154 Calculus Volume 1 18In the following exercises, use the Fundamental Theorem of Calculus, Part 1, to find each derivative. \(\frac{d}{d x} \int_{0}^{\sin x} \sqrt{1-t^{2}} d t\) Text Transcription: d/dx int_0^sin x sqrt 1-t^2 dt
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Chapter 5: Problem 155 Calculus Volume 1 18In the following exercises, use the Fundamental Theorem of Calculus, Part 1, to find each derivative. \(\frac{d}{d x} \int_{\cos x}^{1} \sqrt{1-t^{2}} d t\) Text Transcription: d/dx int_cos x^1 sqrt 1-t^2 dt
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Chapter 5: Problem 156 Calculus Volume 1 18In the following exercises, use the Fundamental Theorem of Calculus, Part 1, to find each derivative. \(\frac{d}{d x} \int_{1}^{\sqrt{x}} \frac{t^{2}}{1+t^{4}} d t\) Text Transcription: d/dx int_1^sqrt x t^2/1+t^4 dt
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Chapter 5: Problem 157 Calculus Volume 1 18In the following exercises, use the Fundamental Theorem of Calculus, Part 1, to find each derivative. \(\frac{d}{d x} \int_{1}^{x^{2}} \frac{\sqrt{t}}{1+t} d t\) Text Transcription: d/dx int_1^x^2 sqrt t/1+t dt
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Chapter 5: Problem 158 Calculus Volume 1 18In the following exercises, use the Fundamental Theorem of Calculus, Part 1, to find each derivative. \(\frac{d}{d x} \int_{0}^{\ln x} e^{t} d t\) Text Transcription: d/dx int_0^ln x e^t dt
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Chapter 5: Problem 159 Calculus Volume 1 18In the following exercises, use the Fundamental Theorem of Calculus, Part 1, to find each derivative. \(\frac{d}{d x} \int_{1}^{e^{2}} \ln u^{2} d u\) Text Transcription: d/dx int_1^e^2 ln u^2 du
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Chapter 5: Problem 160 Calculus Volume 1 18The graph of \(y=\int_{0}^{x} f(t) d t\), where f is a piecewise constant function, is shown here. (a) Over which intervals is f positive? Over which intervals is it negative? Over which intervals, if any, is it equal to zero? (b) What are the maximum and minimum values of f? (c) What is the average value of f? Text Transcription: y=int_0^x f(t) dt
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Chapter 5: Problem 161 Calculus Volume 1 18The graph of \(y=\int_{0}^{x} f(t) d t\), where f is a piecewise constant function, is shown here. a. Over which intervals is f positive? Over which intervals is it negative? Over which intervals, if any, is it equal to zero? b. What are the maximum and minimum values of f? c. What is the average value of f? Text Transcription: y=int_0^x f(t) dt
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Chapter 5: Problem 162 Calculus Volume 1 18The graph of \(y=\int_{0}^{x} \ell(t) d t\), where \(\ell\) is a piecewise linear function, is shown here. a. Over which intervals is \(\ell\) positive? Over which intervals is it negative? Over which, if any, is it zero? b. Over which intervals is \(\ell\) increasing? Over which is it decreasing? Over which, if any, is it constant? c. What is the average value of \(\ell\)? Text Transcription: y=int_0^x ell(t)dt ell
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Chapter 5: Problem 163 Calculus Volume 1 18The graph of \(y=\int_{0}^{x} \ell(t) d t\), where \(\ell\) is a piecewise linear function, is shown here. a. Over which intervals is \(\ell\) positive? Over which intervals is it negative? Over which, if any, is it zero? b. Over which intervals is \(\ell\) increasing? Over which is it decreasing? Over which intervals, if any, is it constant? c. What is the average value of \(\ell\)? Text Transcription: y=int_0^x ell(t)dt ell
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Chapter 5: Problem 164 Calculus Volume 1 18In the following exercises, use a calculator to estimate the area under the curve by computing \(T_{10}\), the average of the left- and right-endpoint Riemann sums using N = 10 rectangles. Then, using the Fundamental Theorem of Calculus, Part 2, determine the exact area. [T] \(y=x^{2}\) over [0,4] Text Transcription: y=x^2
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Chapter 5: Problem 165 Calculus Volume 1 18In the following exercises, use a calculator to estimate the area under the curve by computing \(T_{10}\), the average of the left- and right-endpoint Riemann sums using N = 10 rectangles. Then, using the Fundamental Theorem of Calculus, Part 2, determine the exact area. [T] \(y=x^{3}+6 x^{2}+x-5\) over [-4,2] Text Transcription: T_10 y=x^3+6x^2+x-5
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Chapter 5: Problem 166 Calculus Volume 1 18In the following exercises, use a calculator to estimate the area under the curve by computing \(T_{10}\), the average of the left- and right-endpoint Riemann sums using N = 10 rectangles. Then, using the Fundamental Theorem of Calculus, Part 2, determine the exact area. [T] \(y=\sqrt{x^{3}\) over [0,6] Text Transcription: T_10 y=sqrt x^3
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Chapter 5: Problem 167 Calculus Volume 1 18In the following exercises, use a calculator to estimate the area under the curve by computing \(T_{10}\), the average of the left- and right-endpoint Riemann sums using N = 10 rectangles. Then, using the Fundamental Theorem of Calculus, Part 2, determine the exact area. [T] \(y=\sqrt{x}+x^{2}\) over [1,9] Text Transcription: T_10 y=sqrt x+x^2
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Chapter 5: Problem 168 Calculus Volume 1 18In the following exercises, use a calculator to estimate the area under the curve by computing \(T_{10}\), the average of the left- and right-endpoint Riemann sums using N = 10 rectangles. Then, using the Fundamental Theorem of Calculus, Part 2, determine the exact area. [T] \(\int(\cos x-\sin x) d x\) over \([0, \pi]\) Text Transcription: T_10 int(cos x - sin x) dx\) [0, pi]
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Chapter 5: Problem 169 Calculus Volume 1 18In the following exercises, use a calculator to estimate the area under the curve by computing \(T_{10}\), the average of the left- and right-endpoint Riemann sums using N = 10 rectangles. Then, using the Fundamental Theorem of Calculus, Part 2, determine the exact area. [T] \(\int \frac{4}{x^{2}} d x\) over [1,4] Text Transcription: T_10 int 4/x^2 dx
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Chapter 5: Problem 170 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{-1}^{2}\left(x^{2}-3 x\right) d x\) Text Transcription: int_-1^2 (x^2-3x) dx
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Chapter 5: Problem 171 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{-2}^{3}\left(x^{2}+3 x-5\right) d x\) Text Transcription: int_-2^3 (x^2+3x-5) dx
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Chapter 5: Problem 172 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{-2}^{3}(t+2)(t-3) d t\) Text Transcription: int_-2^3 (t+2)(t-3) dt
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Chapter 5: Problem 173 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{2}^{3}\left(t^{2}-9\right)\left(4-t^{2}\right) d t\) Text Transcription: int_2^3 (t^2-9)(4-t^2) dt
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Chapter 5: Problem 174 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{2} x^{9} d x\) Text Transcription: int_1^2 x^9 dx
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Chapter 5: Problem 175 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{1} x^{99} d x\) Text Transcription: int_0^1 x^99 dx
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Chapter 5: Problem 176 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{4}^{8}\left(4 t^{5 / 2}-3 t^{3 / 2}\right) d t\) Text Transcription: int_4^8 (4 t^5/2}-3 t^3/2) dt
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Chapter 5: Problem 177 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1 / 4}^{4}\left(x^{2}-\frac{1}{x^{2}}\right) d x\) Text Transcription: int_1/4^4 (x^2-1/x^2) dx
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Chapter 5: Problem 178 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{2} \frac{2}{x^{3}} d x\) Text Transcription: int_1^2 2/x^3 dx
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Chapter 5: Problem 179 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{4} \frac{1}{2 \sqrt{x}} d x\) Text Transcription: int_1^4 1/2 sqrt x dx
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Chapter 5: Problem 180 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{4} \frac{2-\sqrt{t}}{t^{2}} d t\) Text Transcription: int_1^4 2-sqrt t/t^2 dt
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Chapter 5: Problem 181 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{16} \frac{d t}{t^{1 / 4}}\) Text Transcription: int_1^16 dt/t^1/4
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Chapter 5: Problem 182 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{2 \pi} \cos \theta d \theta\) Text Transcription: int_0^2 pi cos theta d theta
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Chapter 5: Problem 183 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{\pi / 2} \sin \theta d \theta\) Text Transcription: int_0^pi/2 sin theta d theta
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Chapter 5: Problem 184 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{\pi / 4} \sec ^{2} \theta d \theta\) Text Transcription: int_0^pi/4 sec^2 theta d theta
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Chapter 5: Problem 185 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{\pi / 4} \sec \theta \tan \theta\) Text Transcription: int_0^pi/4 sec theta tan theta
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Chapter 5: Problem 186 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{\pi / 3}^{\pi / 4} \csc \theta \cot \theta d \theta\) Text Transcription: int_pi/3^pi/4} csc theta cot theta d theta
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Chapter 5: Problem 187 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{\pi / 4}^{\pi / 2} \csc ^{2} \theta d \theta\) Text Transcription: int_pi/4^pi/2 csc^2 theta d theta
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Chapter 5: Problem 188 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{2}\left(\frac{1}{t^{2}}-\frac{1}{t^{3}}\right) d t\) Text Transcription: int_1^2 (1/t^2-1/t^3) dt
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Chapter 5: Problem 189 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{-2}^{-1}\left(\frac{1}{t^{2}}-\frac{1}{t^{3}}\right) d t\) Text Transcription: int_-2^-1 (1/t^2-1/t^3) dt
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Chapter 5: Problem 190 Calculus Volume 1 18In the following exercises, use the evaluation theorem to express the integral as a function F(x). \(\int_{a}^{x} t^{2} d t\) Text Transcription: int_a^x t^2 dt
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Chapter 5: Problem 191 Calculus Volume 1 18In the following exercises, use the evaluation theorem to express the integral as a function F(x). \(\int_{1}^{x} e^{t} d t\) Text Transcription: int_1^x e^t dt
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Chapter 5: Problem 192 Calculus Volume 1 18In the following exercises, use the evaluation theorem to express the integral as a function F(x). \(\int_{0}^{x} \cos t d t\) Text Transcription: int_0^x cos tdt
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Chapter 5: Problem 193 Calculus Volume 1 18In the following exercises, use the evaluation theorem to express the integral as a function F(x). \(\int_{-x}^{x} \sin t d t\) Text Transcription: int_-x^x sin tdt
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Chapter 5: Problem 194 Calculus Volume 1 18In the following exercises, identify the roots of the integrand to remove absolute values, then evaluate using the Fundamental Theorem of Calculus, Part 2. \(\int_{-2}^{3}|x| d x\) Text Transcription: int_-2^3|x| dx
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Chapter 5: Problem 195 Calculus Volume 1 18In the following exercises, identify the roots of the integrand to remove absolute values, then evaluate using the Fundamental Theorem of Calculus, Part 2. \(\int_{-2}^{4}\left|t^{2}-2 t-3\right| d t\) Text Transcription: int_-2^4 |t^2-2t-3| dt
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Chapter 5: Problem 196 Calculus Volume 1 18In the following exercises, identify the roots of the integrand to remove absolute values, then evaluate using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{\pi}|\cos t| d t\) Text Transcription: int_0^p |cos t| dt
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Chapter 5: Problem 197 Calculus Volume 1 18In the following exercises, identify the roots of the integrand to remove absolute values, then evaluate using the Fundamental Theorem of Calculus, Part 2. \(\int_{-\pi / 2}^{\pi / 2}|\sin t| d t\) Text Transcription: int_-pi/2^pi/2 |sin t| dt
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Chapter 5: Problem 198 Calculus Volume 1 18Suppose that the number of hours of daylight on a given day in Seattle is modeled by the function \(-3.75 \cos \left(\frac{\pi t}{6}\right)+12.25\), with t given in months and t=0 corresponding to the winter solstice. (a) What is the average number of daylight hours in a year? (b) At which times \(t_{1}\) and \(t_{2}\), where \(0 \leq t_{1}<t_{2}<12\), do the number of daylight hours equal the average number? (c) Write an integral that expresses the total number of daylight hours in Seattle between \(t_{1}\) and \(t_{2}\). (d) Compute the mean hours of daylight in Seattle between \(t_{1}\) and \(t_{2}\), where \(0 \leq t_{1}<t_{2}<12\), and then between \(t_{2}\) and \(t_{1}\), and show that the average of the two is equal to the average day length. Text Transcription: -3.75 cos(pi t/6)+12.25 t_1 t_2 0 leq t_1<t_2<12
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Chapter 5: Problem 199 Calculus Volume 1 18Suppose the rate of gasoline consumption in the United States can be modeled by a sinusoidal function of the form \(\left(11.21-\cos \left(\frac{\pi t}{6}\right)\right) \times 10^{9} \mathrm{gal} / \mathrm{mo}\). (a) What is the average monthly consumption, and for which values of t is the rate at time t equal to the average rate? (b) What is the number of gallons of gasoline consumed in the United States in a year? (c) Write an integral that expresses the average monthly U.S. gas consumption during the part of the year between the beginning of April (t=3) and the end of September (t=9). Text Transcription: (11.21-cos (pi t/6)) times 10^9 gal/mo
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Chapter 5: Problem 200 Calculus Volume 1 18Explain why, if f is continuous over [a, b], there is at least one point \(c \in[a, b]\) such that \(f(c)=\frac{1}{b-a} \int_{a}^{b} f(t) d t\). Text Transcription: c in[a, b] f(c)=1/b-a int_a^b f(t) dt
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Chapter 5: Problem 201 Calculus Volume 1 18Explain why, if f is continuous over [a, b] and is not equal to a constant, there is at least one point \(M \in[a, b]\) such that \(f(M)=\frac{1}{b-a} \int_{a}^{b} f(t) d t\) and at least one point \(m \in[a, b]\) such that \(f(m)<\frac{1}{b-a} \int_{a}^{b} f(t) d t\). Text Transcription: M in[a, b] f(M)=1/b-a int_a^b f(t) dt m in[a, b] f(m)<1/b-a int_a^b f(t) dt
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Chapter 5: Problem 202 Calculus Volume 1 18Kepler’s first law states that the planets move in 206. elliptical orbits with the Sun at one focus. The closest point of a planetary orbit to the Sun is called the perihelion (for Earth, it currently occurs around January 3) and the farthest point is called the aphelion (for Earth, it currently occurs around July 4). Kepler’s second law states that planets sweep out equal areas of their elliptical orbits in equal times. Thus, the two arcs indicated in the following figure are swept out in equal times. At what time of year is Earth moving fastest in its orbit? When is it moving slowest?
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Chapter 5: Problem 203 Calculus Volume 1 18A point on an ellipse with major axis length 2a and minor axis length 2b has the coordinates \((a \cos \theta, b \sin \theta)\), \(0 \leq \theta \leq 2 \pi\). (a) Show that the distance from this point to the focus at (-c, 0) is \(d(\theta)=a+c \cos \theta\), where \(c=\sqrt{a^{2}-b^{2}}\) (b) Use these coordinates to show that the average distance \(\bar{d}\) from a point on the ellipse to the focus at (-c, 0), with respect to angle \(\theta\), is a. Text Transcription: (a cos theta, b sin theta) 0 leq theta leq 2 pi d(theta)=a+c cos theta c=sqrt a^2-b^2 bar d theta
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Chapter 5: Problem 204 Calculus Volume 1 18As implied earlier, according to Kepler’s laws, Earth’s orbit is an ellipse with the Sun at one focus. The perihelion for Earth’s orbit around the Sun is 147,098,290 km and the aphelion is 152,098,232 km. (a) By placing the major axis along the x-axis, find the average distance from Earth to the Sun. (b) The classic definition of an astronomical unit (AU) is the distance from Earth to the Sun, and its value was computed as the average of the perihelion and aphelion distances. Is this definition justified?
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Chapter 5: Problem 205 Calculus Volume 1 18The force of gravitational attraction between the Sun and a planet is \(F(\theta)=\frac{G m M}{r^{2}(\theta)}\), where m is the mass of the planet, M is the mass of the Sun, G is a universal constant, and \(r(\theta)\) is the distance between the Sun and the planet when the planet is at an angle \(\theta\) with the major axis of its orbit. Assuming that M, m, and the ellipse parameters a and b (half-lengths of the major and minor axes) are given, set up-but do not evaluate-an integral that expresses in terms of G, m, M, a, b the average gravitational force between the Sun and the planet. Text Transcription: F(theta)=G m M/r^2(theta) r(theta) theta
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Chapter 5: Problem 206 Calculus Volume 1 18The displacement from rest of a mass attached to a spring satisfies the simple harmonic motion equation \(x(t)=A \cos (\omega t-\phi)\), where \(\phi\) is a phase constant, \(\omega\) is the angular frequency, and A is the amplitude. Find the average velocity, the average speed (magnitude of velocity), the average displacement, and the average distance from rest (magnitude of displacement) of the mass. Text Transcription: x(t)=A \cos (\omega t-\phi) phi omega
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Chapter 5: Problem 174 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{2} x^{9} d x\) Text Transcription: int_1^2 x^9 dx
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Chapter 5: Problem 175 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{1} x^{99} d x\) Text Transcription: int_0^1 x^99 dx
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Chapter 5: Problem 176 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{4}^{8}\left(4 t^{5 / 2}-3 t^{3 / 2}\right) d t\) Text Transcription: int_4^8 (4 t^5/2}-3 t^3/2) dt
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Chapter 5: Problem 177 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1 / 4}^{4}\left(x^{2}-\frac{1}{x^{2}}\right) d x\) Text Transcription: int_1/4^4 (x^2-1/x^2) dx
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Chapter 5: Problem 178 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{2} \frac{2}{x^{3}} d x\) Text Transcription: int_1^2 2/x^3 dx
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Chapter 5: Problem 179 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{4} \frac{1}{2 \sqrt{x}} d x\) Text Transcription: int_1^4 1/2 sqrt x dx
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Chapter 5: Problem 180 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{4} \frac{2-\sqrt{t}}{t^{2}} d t\) Text Transcription: int_1^4 2-sqrt t/t^2 dt
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Chapter 5: Problem 181 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{16} \frac{d t}{t^{1 / 4}}\) Text Transcription: int_1^16 dt/t^1/4
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Chapter 5: Problem 182 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{2 \pi} \cos \theta d \theta\) Text Transcription: int_0^2 pi cos theta d theta
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Chapter 5: Problem 183 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{\pi / 2} \sin \theta d \theta\) Text Transcription: int_0^pi/2 sin theta d theta
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Chapter 5: Problem 184 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{\pi / 4} \sec ^{2} \theta d \theta\) Text Transcription: int_0^pi/4 sec^2 theta d theta
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Chapter 5: Problem 185 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{\pi / 4} \sec \theta \tan \theta\) Text Transcription: int_0^pi/4 sec theta tan theta
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Chapter 5: Problem 186 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{\pi / 3}^{\pi / 4} \csc \theta \cot \theta d \theta\) Text Transcription: int_pi/3^pi/4} csc theta cot theta d theta
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Chapter 5: Problem 187 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{\pi / 4}^{\pi / 2} \csc ^{2} \theta d \theta\) Text Transcription: int_pi/4^pi/2 csc^2 theta d theta
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Chapter 5: Problem 188 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{2}\left(\frac{1}{t^{2}}-\frac{1}{t^{3}}\right) d t\) Text Transcription: int_1^2 (1/t^2-1/t^3) dt
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Chapter 5: Problem 189 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{-2}^{-1}\left(\frac{1}{t^{2}}-\frac{1}{t^{3}}\right) d t\) Text Transcription: int_-2^-1 (1/t^2-1/t^3) dt
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Chapter 5: Problem 190 Calculus Volume 1 18In the following exercises, use the evaluation theorem to express the integral as a function F(x). \(\int_{a}^{x} t^{2} d t\) Text Transcription: int_a^x t^2 dt
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Chapter 5: Problem 191 Calculus Volume 1 18In the following exercises, use the evaluation theorem to express the integral as a function F(x). \(\int_{1}^{x} e^{t} d t\) Text Transcription: int_1^x e^t dt
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Chapter 5: Problem 192 Calculus Volume 1 18In the following exercises, use the evaluation theorem to express the integral as a function F(x). \(\int_{0}^{x} \cos t d t\) Text Transcription: int_0^x cos tdt
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Chapter 5: Problem 193 Calculus Volume 1 18In the following exercises, use the evaluation theorem to express the integral as a function F(x). \(\int_{-x}^{x} \sin t d t\) Text Transcription: int_-x^x sin tdt
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Chapter 5: Problem 194 Calculus Volume 1 18In the following exercises, identify the roots of the integrand to remove absolute values, then evaluate using the Fundamental Theorem of Calculus, Part 2. \(\int_{-2}^{3}|x| d x\) Text Transcription: int_-2^3|x| dx
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Chapter 5: Problem 195 Calculus Volume 1 18In the following exercises, identify the roots of the integrand to remove absolute values, then evaluate using the Fundamental Theorem of Calculus, Part 2. \(\int_{-2}^{4}\left|t^{2}-2 t-3\right| d t\) Text Transcription: int_-2^4 |t^2-2t-3| dt
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Chapter 5: Problem 196 Calculus Volume 1 18In the following exercises, identify the roots of the integrand to remove absolute values, then evaluate using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{\pi}|\cos t| d t\) Text Transcription: int_0^p |cos t| dt
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Chapter 5: Problem 197 Calculus Volume 1 18In the following exercises, identify the roots of the integrand to remove absolute values, then evaluate using the Fundamental Theorem of Calculus, Part 2. \(\int_{-\pi / 2}^{\pi / 2}|\sin t| d t\) Text Transcription: int_-pi/2^pi/2 |sin t| dt
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Chapter 5: Problem 198 Calculus Volume 1 18Suppose that the number of hours of daylight on a given day in Seattle is modeled by the function \(-3.75 \cos \left(\frac{\pi t}{6}\right)+12.25\), with t given in months and t=0 corresponding to the winter solstice. (a) What is the average number of daylight hours in a year? (b) At which times \(t_{1}\) and \(t_{2}\), where \(0 \leq t_{1}<t_{2}<12\), do the number of daylight hours equal the average number? (c) Write an integral that expresses the total number of daylight hours in Seattle between \(t_{1}\) and \(t_{2}\). (d) Compute the mean hours of daylight in Seattle between \(t_{1}\) and \(t_{2}\), where \(0 \leq t_{1}<t_{2}<12\), and then between \(t_{2}\) and \(t_{1}\), and show that the average of the two is equal to the average day length. Text Transcription: -3.75 cos(pi t/6)+12.25 t_1 t_2 0 leq t_1<t_2<12
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Chapter 5: Problem 199 Calculus Volume 1 18Suppose the rate of gasoline consumption in the United States can be modeled by a sinusoidal function of the form \(\left(11.21-\cos \left(\frac{\pi t}{6}\right)\right) \times 10^{9} \mathrm{gal} / \mathrm{mo}\). (a) What is the average monthly consumption, and for which values of t is the rate at time t equal to the average rate? (b) What is the number of gallons of gasoline consumed in the United States in a year? (c) Write an integral that expresses the average monthly U.S. gas consumption during the part of the year between the beginning of April (t=3) and the end of September (t=9). Text Transcription: (11.21-cos (pi t/6)) times 10^9 gal/mo
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Chapter 5: Problem 200 Calculus Volume 1 18Explain why, if f is continuous over [a, b], there is at least one point \(c \in[a, b]\) such that \(f(c)=\frac{1}{b-a} \int_{a}^{b} f(t) d t\). Text Transcription: c in[a, b] f(c)=1/b-a int_a^b f(t) dt
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Chapter 5: Problem 201 Calculus Volume 1 18Explain why, if f is continuous over [a, b] and is not equal to a constant, there is at least one point \(M \in[a, b]\) such that \(f(M)=\frac{1}{b-a} \int_{a}^{b} f(t) d t\) and at least one point \(m \in[a, b]\) such that \(f(m)<\frac{1}{b-a} \int_{a}^{b} f(t) d t\). Text Transcription: M in[a, b] f(M)=1/b-a int_a^b f(t) dt m in[a, b] f(m)<1/b-a int_a^b f(t) dt
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Chapter 5: Problem 202 Calculus Volume 1 18Kepler’s first law states that the planets move in 206. elliptical orbits with the Sun at one focus. The closest point of a planetary orbit to the Sun is called the perihelion (for Earth, it currently occurs around January 3) and the farthest point is called the aphelion (for Earth, it currently occurs around July 4). Kepler’s second law states that planets sweep out equal areas of their elliptical orbits in equal times. Thus, the two arcs indicated in the following figure are swept out in equal times. At what time of year is Earth moving fastest in its orbit? When is it moving slowest?
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Chapter 5: Problem 203 Calculus Volume 1 18A point on an ellipse with major axis length 2a and minor axis length 2b has the coordinates \((a \cos \theta, b \sin \theta)\), \(0 \leq \theta \leq 2 \pi\). (a) Show that the distance from this point to the focus at (-c, 0) is \(d(\theta)=a+c \cos \theta\), where \(c=\sqrt{a^{2}-b^{2}}\) (b) Use these coordinates to show that the average distance \(\bar{d}\) from a point on the ellipse to the focus at (-c, 0), with respect to angle \(\theta\), is a. Text Transcription: (a cos theta, b sin theta) 0 leq theta leq 2 pi d(theta)=a+c cos theta c=sqrt a^2-b^2 bar d theta
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Chapter 5: Problem 204 Calculus Volume 1 18As implied earlier, according to Kepler’s laws, Earth’s orbit is an ellipse with the Sun at one focus. The perihelion for Earth’s orbit around the Sun is 147,098,290 km and the aphelion is 152,098,232 km. (a) By placing the major axis along the x-axis, find the average distance from Earth to the Sun. (b) The classic definition of an astronomical unit (AU) is the distance from Earth to the Sun, and its value was computed as the average of the perihelion and aphelion distances. Is this definition justified?
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Chapter 5: Problem 205 Calculus Volume 1 18The force of gravitational attraction between the Sun and a planet is \(F(\theta)=\frac{G m M}{r^{2}(\theta)}\), where m is the mass of the planet, M is the mass of the Sun, G is a universal constant, and \(r(\theta)\) is the distance between the Sun and the planet when the planet is at an angle \(\theta\) with the major axis of its orbit. Assuming that M, m, and the ellipse parameters a and b (half-lengths of the major and minor axes) are given, set up-but do not evaluate-an integral that expresses in terms of G, m, M, a, b the average gravitational force between the Sun and the planet. Text Transcription: F(theta)=G m M/r^2(theta) r(theta) theta
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Chapter 5: Problem 206 Calculus Volume 1 18The displacement from rest of a mass attached to a spring satisfies the simple harmonic motion equation \(x(t)=A \cos (\omega t-\phi)\), where \(\phi\) is a phase constant, \(\omega\) is the angular frequency, and A is the amplitude. Find the average velocity, the average speed (magnitude of velocity), the average displacement, and the average distance from rest (magnitude of displacement) of the mass. Text Transcription: x(t)=A \cos (\omega t-\phi) phi omega
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Chapter 5: Problem 174 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{2} x^{9} d x\) Text Transcription: int_1^2 x^9 dx
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Chapter 5: Problem 175 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{1} x^{99} d x\) Text Transcription: int_0^1 x^99 dx
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Chapter 5: Problem 176 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{4}^{8}\left(4 t^{5 / 2}-3 t^{3 / 2}\right) d t\) Text Transcription: int_4^8 (4 t^5/2}-3 t^3/2) dt
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Chapter 5: Problem 177 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1 / 4}^{4}\left(x^{2}-\frac{1}{x^{2}}\right) d x\) Text Transcription: int_1/4^4 (x^2-1/x^2) dx
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Chapter 5: Problem 178 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{2} \frac{2}{x^{3}} d x\) Text Transcription: int_1^2 2/x^3 dx
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Chapter 5: Problem 179 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{4} \frac{1}{2 \sqrt{x}} d x\) Text Transcription: int_1^4 1/2 sqrt x dx
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Chapter 5: Problem 180 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{4} \frac{2-\sqrt{t}}{t^{2}} d t\) Text Transcription: int_1^4 2-sqrt t/t^2 dt
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Chapter 5: Problem 181 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{16} \frac{d t}{t^{1 / 4}}\) Text Transcription: int_1^16 dt/t^1/4
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Chapter 5: Problem 182 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{2 \pi} \cos \theta d \theta\) Text Transcription: int_0^2 pi cos theta d theta
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Chapter 5: Problem 183 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{\pi / 2} \sin \theta d \theta\) Text Transcription: int_0^pi/2 sin theta d theta
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Chapter 5: Problem 184 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{\pi / 4} \sec ^{2} \theta d \theta\) Text Transcription: int_0^pi/4 sec^2 theta d theta
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Chapter 5: Problem 185 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{\pi / 4} \sec \theta \tan \theta\) Text Transcription: int_0^pi/4 sec theta tan theta
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Chapter 5: Problem 186 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{\pi / 3}^{\pi / 4} \csc \theta \cot \theta d \theta\) Text Transcription: int_pi/3^pi/4} csc theta cot theta d theta
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Chapter 5: Problem 187 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{\pi / 4}^{\pi / 2} \csc ^{2} \theta d \theta\) Text Transcription: int_pi/4^pi/2 csc^2 theta d theta
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Chapter 5: Problem 188 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{2}\left(\frac{1}{t^{2}}-\frac{1}{t^{3}}\right) d t\) Text Transcription: int_1^2 (1/t^2-1/t^3) dt
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Chapter 5: Problem 189 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{-2}^{-1}\left(\frac{1}{t^{2}}-\frac{1}{t^{3}}\right) d t\) Text Transcription: int_-2^-1 (1/t^2-1/t^3) dt
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Chapter 5: Problem 190 Calculus Volume 1 18In the following exercises, use the evaluation theorem to express the integral as a function F(x). \(\int_{a}^{x} t^{2} d t\) Text Transcription: int_a^x t^2 dt
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Chapter 5: Problem 191 Calculus Volume 1 18In the following exercises, use the evaluation theorem to express the integral as a function F(x). \(\int_{1}^{x} e^{t} d t\) Text Transcription: int_1^x e^t dt
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Chapter 5: Problem 192 Calculus Volume 1 18In the following exercises, use the evaluation theorem to express the integral as a function F(x). \(\int_{0}^{x} \cos t d t\) Text Transcription: int_0^x cos tdt
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Chapter 5: Problem 193 Calculus Volume 1 18In the following exercises, use the evaluation theorem to express the integral as a function F(x). \(\int_{-x}^{x} \sin t d t\) Text Transcription: int_-x^x sin tdt
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Chapter 5: Problem 194 Calculus Volume 1 18In the following exercises, identify the roots of the integrand to remove absolute values, then evaluate using the Fundamental Theorem of Calculus, Part 2. \(\int_{-2}^{3}|x| d x\) Text Transcription: int_-2^3|x| dx
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Chapter 5: Problem 195 Calculus Volume 1 18In the following exercises, identify the roots of the integrand to remove absolute values, then evaluate using the Fundamental Theorem of Calculus, Part 2. \(\int_{-2}^{4}\left|t^{2}-2 t-3\right| d t\) Text Transcription: int_-2^4 |t^2-2t-3| dt
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Chapter 5: Problem 196 Calculus Volume 1 18In the following exercises, identify the roots of the integrand to remove absolute values, then evaluate using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{\pi}|\cos t| d t\) Text Transcription: int_0^p |cos t| dt
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Chapter 5: Problem 197 Calculus Volume 1 18In the following exercises, identify the roots of the integrand to remove absolute values, then evaluate using the Fundamental Theorem of Calculus, Part 2. \(\int_{-\pi / 2}^{\pi / 2}|\sin t| d t\) Text Transcription: int_-pi/2^pi/2 |sin t| dt
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Chapter 5: Problem 198 Calculus Volume 1 18Suppose that the number of hours of daylight on a given day in Seattle is modeled by the function \(-3.75 \cos \left(\frac{\pi t}{6}\right)+12.25\), with t given in months and t=0 corresponding to the winter solstice. (a) What is the average number of daylight hours in a year? (b) At which times \(t_{1}\) and \(t_{2}\), where \(0 \leq t_{1}<t_{2}<12\), do the number of daylight hours equal the average number? (c) Write an integral that expresses the total number of daylight hours in Seattle between \(t_{1}\) and \(t_{2}\). (d) Compute the mean hours of daylight in Seattle between \(t_{1}\) and \(t_{2}\), where \(0 \leq t_{1}<t_{2}<12\), and then between \(t_{2}\) and \(t_{1}\), and show that the average of the two is equal to the average day length. Text Transcription: -3.75 cos(pi t/6)+12.25 t_1 t_2 0 leq t_1<t_2<12
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Chapter 5: Problem 199 Calculus Volume 1 18Suppose the rate of gasoline consumption in the United States can be modeled by a sinusoidal function of the form \(\left(11.21-\cos \left(\frac{\pi t}{6}\right)\right) \times 10^{9} \mathrm{gal} / \mathrm{mo}\). (a) What is the average monthly consumption, and for which values of t is the rate at time t equal to the average rate? (b) What is the number of gallons of gasoline consumed in the United States in a year? (c) Write an integral that expresses the average monthly U.S. gas consumption during the part of the year between the beginning of April (t=3) and the end of September (t=9). Text Transcription: (11.21-cos (pi t/6)) times 10^9 gal/mo
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Chapter 5: Problem 200 Calculus Volume 1 18Explain why, if f is continuous over [a, b], there is at least one point \(c \in[a, b]\) such that \(f(c)=\frac{1}{b-a} \int_{a}^{b} f(t) d t\). Text Transcription: c in[a, b] f(c)=1/b-a int_a^b f(t) dt
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Chapter 5: Problem 201 Calculus Volume 1 18Explain why, if f is continuous over [a, b] and is not equal to a constant, there is at least one point \(M \in[a, b]\) such that \(f(M)=\frac{1}{b-a} \int_{a}^{b} f(t) d t\) and at least one point \(m \in[a, b]\) such that \(f(m)<\frac{1}{b-a} \int_{a}^{b} f(t) d t\). Text Transcription: M in[a, b] f(M)=1/b-a int_a^b f(t) dt m in[a, b] f(m)<1/b-a int_a^b f(t) dt
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Chapter 5: Problem 202 Calculus Volume 1 18Kepler’s first law states that the planets move in 206. elliptical orbits with the Sun at one focus. The closest point of a planetary orbit to the Sun is called the perihelion (for Earth, it currently occurs around January 3) and the farthest point is called the aphelion (for Earth, it currently occurs around July 4). Kepler’s second law states that planets sweep out equal areas of their elliptical orbits in equal times. Thus, the two arcs indicated in the following figure are swept out in equal times. At what time of year is Earth moving fastest in its orbit? When is it moving slowest?
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Chapter 5: Problem 203 Calculus Volume 1 18A point on an ellipse with major axis length 2a and minor axis length 2b has the coordinates \((a \cos \theta, b \sin \theta)\), \(0 \leq \theta \leq 2 \pi\). (a) Show that the distance from this point to the focus at (-c, 0) is \(d(\theta)=a+c \cos \theta\), where \(c=\sqrt{a^{2}-b^{2}}\) (b) Use these coordinates to show that the average distance \(\bar{d}\) from a point on the ellipse to the focus at (-c, 0), with respect to angle \(\theta\), is a. Text Transcription: (a cos theta, b sin theta) 0 leq theta leq 2 pi d(theta)=a+c cos theta c=sqrt a^2-b^2 bar d theta
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Chapter 5: Problem 204 Calculus Volume 1 18As implied earlier, according to Kepler’s laws, Earth’s orbit is an ellipse with the Sun at one focus. The perihelion for Earth’s orbit around the Sun is 147,098,290 km and the aphelion is 152,098,232 km. (a) By placing the major axis along the x-axis, find the average distance from Earth to the Sun. (b) The classic definition of an astronomical unit (AU) is the distance from Earth to the Sun, and its value was computed as the average of the perihelion and aphelion distances. Is this definition justified?
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Chapter 5: Problem 205 Calculus Volume 1 18The force of gravitational attraction between the Sun and a planet is \(F(\theta)=\frac{G m M}{r^{2}(\theta)}\), where m is the mass of the planet, M is the mass of the Sun, G is a universal constant, and \(r(\theta)\) is the distance between the Sun and the planet when the planet is at an angle \(\theta\) with the major axis of its orbit. Assuming that M, m, and the ellipse parameters a and b (half-lengths of the major and minor axes) are given, set up-but do not evaluate-an integral that expresses in terms of G, m, M, a, b the average gravitational force between the Sun and the planet. Text Transcription: F(theta)=G m M/r^2(theta) r(theta) theta
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Chapter 5: Problem 206 Calculus Volume 1 18The displacement from rest of a mass attached to a spring satisfies the simple harmonic motion equation \(x(t)=A \cos (\omega t-\phi)\), where \(\phi\) is a phase constant, \(\omega\) is the angular frequency, and A is the amplitude. Find the average velocity, the average speed (magnitude of velocity), the average displacement, and the average distance from rest (magnitude of displacement) of the mass. Text Transcription: x(t)=A \cos (\omega t-\phi) phi omega
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Chapter 5: Problem 174 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{2} x^{9} d x\) Text Transcription: int_1^2 x^9 dx
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Chapter 5: Problem 175 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{1} x^{99} d x\) Text Transcription: int_0^1 x^99 dx
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Chapter 5: Problem 176 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{4}^{8}\left(4 t^{5 / 2}-3 t^{3 / 2}\right) d t\) Text Transcription: int_4^8 (4 t^5/2}-3 t^3/2) dt
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Chapter 5: Problem 177 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1 / 4}^{4}\left(x^{2}-\frac{1}{x^{2}}\right) d x\) Text Transcription: int_1/4^4 (x^2-1/x^2) dx
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Chapter 5: Problem 178 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{2} \frac{2}{x^{3}} d x\) Text Transcription: int_1^2 2/x^3 dx
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Chapter 5: Problem 179 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{4} \frac{1}{2 \sqrt{x}} d x\) Text Transcription: int_1^4 1/2 sqrt x dx
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Chapter 5: Problem 180 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{4} \frac{2-\sqrt{t}}{t^{2}} d t\) Text Transcription: int_1^4 2-sqrt t/t^2 dt
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Chapter 5: Problem 181 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{16} \frac{d t}{t^{1 / 4}}\) Text Transcription: int_1^16 dt/t^1/4
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Chapter 5: Problem 182 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{2 \pi} \cos \theta d \theta\) Text Transcription: int_0^2 pi cos theta d theta
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Chapter 5: Problem 183 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{\pi / 2} \sin \theta d \theta\) Text Transcription: int_0^pi/2 sin theta d theta
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Chapter 5: Problem 184 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{\pi / 4} \sec ^{2} \theta d \theta\) Text Transcription: int_0^pi/4 sec^2 theta d theta
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Chapter 5: Problem 185 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{\pi / 4} \sec \theta \tan \theta\) Text Transcription: int_0^pi/4 sec theta tan theta
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Chapter 5: Problem 186 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{\pi / 3}^{\pi / 4} \csc \theta \cot \theta d \theta\) Text Transcription: int_pi/3^pi/4} csc theta cot theta d theta
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Chapter 5: Problem 187 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{\pi / 4}^{\pi / 2} \csc ^{2} \theta d \theta\) Text Transcription: int_pi/4^pi/2 csc^2 theta d theta
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Chapter 5: Problem 188 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{1}^{2}\left(\frac{1}{t^{2}}-\frac{1}{t^{3}}\right) d t\) Text Transcription: int_1^2 (1/t^2-1/t^3) dt
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Chapter 5: Problem 189 Calculus Volume 1 18In the following exercises, evaluate each definite integral using the Fundamental Theorem of Calculus, Part 2. \(\int_{-2}^{-1}\left(\frac{1}{t^{2}}-\frac{1}{t^{3}}\right) d t\) Text Transcription: int_-2^-1 (1/t^2-1/t^3) dt
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Chapter 5: Problem 190 Calculus Volume 1 18In the following exercises, use the evaluation theorem to express the integral as a function F(x). \(\int_{a}^{x} t^{2} d t\) Text Transcription: int_a^x t^2 dt
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Chapter 5: Problem 191 Calculus Volume 1 18In the following exercises, use the evaluation theorem to express the integral as a function F(x). \(\int_{1}^{x} e^{t} d t\) Text Transcription: int_1^x e^t dt
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Chapter 5: Problem 192 Calculus Volume 1 18In the following exercises, use the evaluation theorem to express the integral as a function F(x). \(\int_{0}^{x} \cos t d t\) Text Transcription: int_0^x cos tdt
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Chapter 5: Problem 193 Calculus Volume 1 18In the following exercises, use the evaluation theorem to express the integral as a function F(x). \(\int_{-x}^{x} \sin t d t\) Text Transcription: int_-x^x sin tdt
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Chapter 5: Problem 194 Calculus Volume 1 18In the following exercises, identify the roots of the integrand to remove absolute values, then evaluate using the Fundamental Theorem of Calculus, Part 2. \(\int_{-2}^{3}|x| d x\) Text Transcription: int_-2^3|x| dx
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Chapter 5: Problem 195 Calculus Volume 1 18In the following exercises, identify the roots of the integrand to remove absolute values, then evaluate using the Fundamental Theorem of Calculus, Part 2. \(\int_{-2}^{4}\left|t^{2}-2 t-3\right| d t\) Text Transcription: int_-2^4 |t^2-2t-3| dt
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Chapter 5: Problem 196 Calculus Volume 1 18In the following exercises, identify the roots of the integrand to remove absolute values, then evaluate using the Fundamental Theorem of Calculus, Part 2. \(\int_{0}^{\pi}|\cos t| d t\) Text Transcription: int_0^p |cos t| dt
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Chapter 5: Problem 197 Calculus Volume 1 18In the following exercises, identify the roots of the integrand to remove absolute values, then evaluate using the Fundamental Theorem of Calculus, Part 2. \(\int_{-\pi / 2}^{\pi / 2}|\sin t| d t\) Text Transcription: int_-pi/2^pi/2 |sin t| dt
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Chapter 5: Problem 198 Calculus Volume 1 18Suppose that the number of hours of daylight on a given day in Seattle is modeled by the function \(-3.75 \cos \left(\frac{\pi t}{6}\right)+12.25\), with t given in months and t=0 corresponding to the winter solstice. (a) What is the average number of daylight hours in a year? (b) At which times \(t_{1}\) and \(t_{2}\), where \(0 \leq t_{1}<t_{2}<12\), do the number of daylight hours equal the average number? (c) Write an integral that expresses the total number of daylight hours in Seattle between \(t_{1}\) and \(t_{2}\). (d) Compute the mean hours of daylight in Seattle between \(t_{1}\) and \(t_{2}\), where \(0 \leq t_{1}<t_{2}<12\), and then between \(t_{2}\) and \(t_{1}\), and show that the average of the two is equal to the average day length. Text Transcription: -3.75 cos(pi t/6)+12.25 t_1 t_2 0 leq t_1<t_2<12
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Chapter 5: Problem 199 Calculus Volume 1 18Suppose the rate of gasoline consumption in the United States can be modeled by a sinusoidal function of the form \(\left(11.21-\cos \left(\frac{\pi t}{6}\right)\right) \times 10^{9} \mathrm{gal} / \mathrm{mo}\). (a) What is the average monthly consumption, and for which values of t is the rate at time t equal to the average rate? (b) What is the number of gallons of gasoline consumed in the United States in a year? (c) Write an integral that expresses the average monthly U.S. gas consumption during the part of the year between the beginning of April (t=3) and the end of September (t=9). Text Transcription: (11.21-cos (pi t/6)) times 10^9 gal/mo
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Chapter 5: Problem 200 Calculus Volume 1 18Explain why, if f is continuous over [a, b], there is at least one point \(c \in[a, b]\) such that \(f(c)=\frac{1}{b-a} \int_{a}^{b} f(t) d t\). Text Transcription: c in[a, b] f(c)=1/b-a int_a^b f(t) dt
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Chapter 5: Problem 201 Calculus Volume 1 18Explain why, if f is continuous over [a, b] and is not equal to a constant, there is at least one point \(M \in[a, b]\) such that \(f(M)=\frac{1}{b-a} \int_{a}^{b} f(t) d t\) and at least one point \(m \in[a, b]\) such that \(f(m)<\frac{1}{b-a} \int_{a}^{b} f(t) d t\). Text Transcription: M in[a, b] f(M)=1/b-a int_a^b f(t) dt m in[a, b] f(m)<1/b-a int_a^b f(t) dt
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Chapter 5: Problem 202 Calculus Volume 1 18Kepler’s first law states that the planets move in 206. elliptical orbits with the Sun at one focus. The closest point of a planetary orbit to the Sun is called the perihelion (for Earth, it currently occurs around January 3) and the farthest point is called the aphelion (for Earth, it currently occurs around July 4). Kepler’s second law states that planets sweep out equal areas of their elliptical orbits in equal times. Thus, the two arcs indicated in the following figure are swept out in equal times. At what time of year is Earth moving fastest in its orbit? When is it moving slowest?
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Chapter 5: Problem 203 Calculus Volume 1 18A point on an ellipse with major axis length 2a and minor axis length 2b has the coordinates \((a \cos \theta, b \sin \theta)\), \(0 \leq \theta \leq 2 \pi\). (a) Show that the distance from this point to the focus at (-c, 0) is \(d(\theta)=a+c \cos \theta\), where \(c=\sqrt{a^{2}-b^{2}}\) (b) Use these coordinates to show that the average distance \(\bar{d}\) from a point on the ellipse to the focus at (-c, 0), with respect to angle \(\theta\), is a. Text Transcription: (a cos theta, b sin theta) 0 leq theta leq 2 pi d(theta)=a+c cos theta c=sqrt a^2-b^2 bar d theta
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Chapter 5: Problem 204 Calculus Volume 1 18As implied earlier, according to Kepler’s laws, Earth’s orbit is an ellipse with the Sun at one focus. The perihelion for Earth’s orbit around the Sun is 147,098,290 km and the aphelion is 152,098,232 km. (a) By placing the major axis along the x-axis, find the average distance from Earth to the Sun. (b) The classic definition of an astronomical unit (AU) is the distance from Earth to the Sun, and its value was computed as the average of the perihelion and aphelion distances. Is this definition justified?
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Chapter 5: Problem 205 Calculus Volume 1 18The force of gravitational attraction between the Sun and a planet is \(F(\theta)=\frac{G m M}{r^{2}(\theta)}\), where m is the mass of the planet, M is the mass of the Sun, G is a universal constant, and \(r(\theta)\) is the distance between the Sun and the planet when the planet is at an angle \(\theta\) with the major axis of its orbit. Assuming that M, m, and the ellipse parameters a and b (half-lengths of the major and minor axes) are given, set up-but do not evaluate-an integral that expresses in terms of G, m, M, a, b the average gravitational force between the Sun and the planet. Text Transcription: F(theta)=G m M/r^2(theta) r(theta) theta
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Chapter 5: Problem 206 Calculus Volume 1 18The displacement from rest of a mass attached to a spring satisfies the simple harmonic motion equation \(x(t)=A \cos (\omega t-\phi)\), where \(\phi\) is a phase constant, \(\omega\) is the angular frequency, and A is the amplitude. Find the average velocity, the average speed (magnitude of velocity), the average displacement, and the average distance from rest (magnitude of displacement) of the mass. Text Transcription: x(t)=A \cos (\omega t-\phi) phi omega
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