Review 5: Areas Between Curves - Now You Try I-2

1. Find the area of the region bounded by the curves $LaTeX: y=\sqrt{x+2}$ $y=\sqrt{x+2}$ , $LaTeX: y=x\sqrt{4-x^2}$ $y=x\sqrt{4-x^2}$ , when $LaTeX: x\le 1$ $x\le 1$ .

Solution:

▶ Show

In the region $LaTeX: x\le 1$

$x\le 1$ , the first two curves intersect at LaTeX: (-2,0)

$(-2,0)$ and $LaTeX: (1,\sqrt{3})$

$(1,\sqrt{3})$ . When LaTeX: x=0

$x=0$ we see that the first curve is at $LaTeX: y=\sqrt{2}$

$y=\sqrt{2}$ and the second is at LaTeX: y=0

$y=0$ , so the second curve is higher than the first in between LaTeX: x=-2

$x=-2$ and LaTeX: x=1

$x=1$ . The area is then $LaTeX: \begin{align*} A&=\int_{-2}^1 \sqrt{x+2}-x\sqrt{4-x^2} \, dx \\ &=\tfrac23 (x+2)^{3/2}+\tfrac13 (4-x^2)^{3/2}\Big|_{-2}^1 \\ &=\tfrac23 (3)^{3/2}+\tfrac13 (3)^{3/2} \\ &=3^{3/2}. \end{align*}$

$\begin{align*} A&=\int_{-2}^1 \sqrt{x+2}-x\sqrt{4-x^2} \, dx \\ &=\tfrac23 (x+2)^{3/2}+\tfrac13 (4-x^2)^{3/2}\Big|_{-2}^1 \\ &=\tfrac23 (3)^{3/2}+\tfrac13 (3)^{3/2} \\ &=3^{3/2}. \end{align*}$

2. Challenge: Find the area bounded between the function $LaTeX: y=\sqrt{2-x^2}$ $y=\sqrt{2-x^2}$ , LaTeX: y=1/x $y=1/x$ , LaTeX: x=4 $x=4$ , and the $x$ -axis.

Solution:

▶ Show

A diagram of the region in question is given below. Area Problem 2.png

We can see that the curves LaTeX: y=1/x

$y=1/x$ and $LaTeX: y=\sqrt{2-x^2}$

$y=\sqrt{2-x^2}$ intersect at the point LaTeX: (1,1)

$(1,1)$ , and $LaTeX: y=\sqrt{2-x^2}$

$y=\sqrt{2-x^2}$ intersects the LaTeX: x

$x$ -axis at $LaTeX: (\sqrt{2},0)$

$(\sqrt{2},0)$ . Hence we can write the area as an integral $LaTeX: A=\int_1^{\sqrt{2}} \frac1x-\sqrt{2-x^2} \, dx + \int_{\sqrt{2}}^4 \frac1x \, dx$

$A=\int_1^{\sqrt{2}} \frac1x-\sqrt{2-x^2} \, dx + \int_{\sqrt{2}}^4 \frac1x \, dx$ There are two ways to compute this integral, either using trigonometric substitution or geometry.

▶ Show

Approach 1) Let's rewrite LaTeX: A

$A$ as $LaTeX: A=\int_1^4 \tfrac1x \, dx - \int_1^{\sqrt{2}} \sqrt{2-x^2} \, dx=\ln 4-\int_1^{\sqrt{2}} \sqrt{2-x^2} \, dx.$

$A=\int_1^4 \tfrac1x \, dx - \int_1^{\sqrt{2}} \sqrt{2-x^2} \, dx=\ln 4-\int_1^{\sqrt{2}} \sqrt{2-x^2} \, dx.$ To compute the second integral, we use trigonometric substitution; specifically, substitute $LaTeX: x=\sqrt2\sin(\theta)$

$x=\sqrt2\sin(\theta)$ , so $LaTeX: dx=\sqrt2\cos(\theta) \, d\theta$

$dx=\sqrt2\cos(\theta) \, d\theta$ . Then $LaTeX: \begin{align*} \int_1^{\sqrt{2}} \sqrt{2-x^2} \, dx&=\int_{x=1}^{x=\sqrt{2}} \sqrt{2-2\sin^2(\theta)} \sqrt{2}\cos(\theta) \, d\theta \\ &=\int_{x=1}^{x=\sqrt{2}} 2\cos^2(\theta) \, d\theta \\ &=\int_{x=1}^{x=\sqrt{2}} \cos(2\theta)+1 \, d\theta \\ &=\tfrac12 \sin(2\theta)+\theta\Big|_{x=1}^{x=\sqrt{2}} \\ &=\sin(\theta)\cos(\theta)+\theta\Big|_{x=1}^{x=\sqrt{2}} \\ &=\sin(\theta)\sqrt{1-\sin^2(\theta)}+\theta\Big|_{x=1}^{x=\sqrt{2}} \\ &=\tfrac{x}{\sqrt{2}}\sqrt{1-\tfrac{x^2}{2}}+\arcsin(\tfrac{x}{\sqrt{2}}) \Big|_{1}^{\sqrt{2}} \\ &=0+\arcsin(1)-\tfrac{1}{\sqrt{2}}\sqrt{\tfrac{1}{2}}-\arcsin(\tfrac1{\sqrt{2}}) \\ &=\tfrac\pi4-\tfrac12. \end{align*}$

$\begin{align*} \int_1^{\sqrt{2}} \sqrt{2-x^2} \, dx&=\int_{x=1}^{x=\sqrt{2}} \sqrt{2-2\sin^2(\theta)} \sqrt{2}\cos(\theta) \, d\theta \\ &=\int_{x=1}^{x=\sqrt{2}} 2\cos^2(\theta) \, d\theta \\ &=\int_{x=1}^{x=\sqrt{2}} \cos(2\theta)+1 \, d\theta \\ &=\tfrac12 \sin(2\theta)+\theta\Big|_{x=1}^{x=\sqrt{2}} \\ &=\sin(\theta)\cos(\theta)+\theta\Big|_{x=1}^{x=\sqrt{2}} \\ &=\sin(\theta)\sqrt{1-\sin^2(\theta)}+\theta\Big|_{x=1}^{x=\sqrt{2}} \\ &=\tfrac{x}{\sqrt{2}}\sqrt{1-\tfrac{x^2}{2}}+\arcsin(\tfrac{x}{\sqrt{2}}) \Big|_{1}^{\sqrt{2}} \\ &=0+\arcsin(1)-\tfrac{1}{\sqrt{2}}\sqrt{\tfrac{1}{2}}-\arcsin(\tfrac1{\sqrt{2}}) \\ &=\tfrac\pi4-\tfrac12. \end{align*}$ Thus $LaTeX: A=\ln 4+\tfrac12-\pi/4$

$A=\ln 4+\tfrac12-\pi/4$ .

▶ Show

Approach 2) We can use geometry to find the area of the region. The blue curve above is the graph of a semicircle with radius $LaTeX: \sqrt{2}$

$\sqrt{2}$ , so we can reinterpret the area as the difference between two quantities, the area under the curve LaTeX: y=1/x

$y=1/x$ from LaTeX: x=1

$x=1$ to

$x=4$ , and this red region of the circle Area Problem 4.png

This red region is the difference between a sector of the circle and a triangle, as seen below. Area Problem 5.png

Thus the area is given by $LaTeX: \begin{align*} A&=\int_1^4 \frac1x \, dx-(Sector-Triangle) \\&=\ln(4)-\ln(1)-\Big(\tfrac{\pi (\sqrt{2})^2}{8}-\tfrac12\Big) \\ &=\ln(4)-\tfrac{\pi}{4}+\tfrac12. \end{align*}$

$\begin{align*} A&=\int_1^4 \frac1x \, dx-(Sector-Triangle) \\&=\ln(4)-\ln(1)-\Big(\tfrac{\pi (\sqrt{2})^2}{8}-\tfrac12\Big) \\ &=\ln(4)-\tfrac{\pi}{4}+\tfrac12. \end{align*}$