Learning Outcomes
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Compute arclengths related to two-dimensional parametric/vector equations.
Section 7.3 Parametric/Vector Arclength (CO3)
Subsection 7.3.1 Activities
Example 7.3.1.
In FigureΒ 102, the blue curve is the graph of the parametric equations \(x=t^2\) and \(y=t^3\) for \(1\leq t\leq 2\text{.}\) This curve connects the point \((1,1)\) to the point \((4,8)\text{.}\) The red dashed line is the straight line segment connecting these points.
Diagram Exploration Keyboard Controls
Activity 7.3.2.
Letβs first investigate the length of the dashed red line segment in FigureΒ 102.
(a)
Draw a right triangle with the red dashed line segment as its hypotenuse, one leg parallel to the \(x\)-axis, and the other parallel to the \(y\)-axis.
How long are these legs?
(b)
The Pythagorean theorem states that for a right triangle with leg lengths \(a,b\) and hypotenuse length \(c\text{,}\) we have...
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\(a=b=c\text{.}\)
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\(a+b=c\text{.}\)
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\(a^2=b^2=c^2\text{.}\)
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\(a^2+b^2=c^2\text{.}\)
(c)
Using the leg lengths and Pythagorean theorem, how long must the red dashed hypotenuse be?
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\(\sqrt{20}\approx 4.47\text{.}\)
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\(\sqrt{58}\approx 7.62\text{.}\)
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\(\sqrt{67}\approx 8.19\text{.}\)
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\(\sqrt{100}=10\text{.}\)
(d)
Compared with the blue parametric curve connecting the same two points, is the red dashed line segment length an overestimate or underestimate?
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Overestimate: the blue curve is shorter than the red line.
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Underestimate: the blue curve is longer than the red line.
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Exact: the blue curve is exactly as long as the red line.
Fact 7.3.3.
Recall that the linear distance between two points \((x_1,y_1)\) and \((x_2,y_2)\) may be computed by the distance formula
\begin{equation*}
\sqrt{(x_2-x_1)^2+(y_2-y_1)^2}\text{.}
\end{equation*}
Note that \(\Delta x=|x_2-x_1|\) and \(\Delta y=|y_2-y_1|\) measure leg lengths of a right triangle whose hypotenuse is the distance we want to measure, so we may rewrite this formula as
\begin{equation*}
\sqrt{(\Delta x)^2+(\Delta y)^2}\text{.}
\end{equation*}
This formula will need to be modified to measure a curved path between two points.
Observation 7.3.4.
By approximating the curve by several (say \(N\)) segments connecting points along the curve, we obtain a better approximation than a single line segment. For example, the illustration shown in FigureΒ 103 gives three segments whose distances sum to about \(7.6315\text{,}\) while the actual length of the curve turns out to be about \(7.6337\text{.}\)
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Activity 7.3.5.
How should we modify the distance formula \(\sqrt{(\Delta x)^2+(\Delta y)^2}\) to measure arclength as illustrated in FigureΒ 103?
(a)
Let \(\Delta L_1,\Delta L_2,\Delta L_3\) describe the lengths of each of the three segments. Which expression describes the total length of these segments?
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\(\displaystyle \Delta L_1\times \Delta L_2\times \Delta L_3\)
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\(\displaystyle \Delta L_1+ 2\Delta L_2+ 3\Delta L_3\)
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\(\displaystyle \sum_{i=1}^{3} \Delta L_i\)
(b)
We can let each \(\Delta L_i=\sqrt{(\Delta x_i)^2+(\Delta y_i)^2}\text{.}\) But we will find it useful to involve the parameter \(t\) as well, or more accurately, the change \(\Delta t_i\) of \(t\) between each point of the subdivision.
Which of these is algebraically the same as the above formula for \(\Delta L_i\text{?}\)
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\(\displaystyle \sqrt{\left(\frac{\Delta x_i}{\Delta t_i}\right)^2+\left(\frac{\Delta y_i}{\Delta t_i}\right)^2}\)
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\(\displaystyle \sqrt{\left[\left(\frac{\Delta x_i}{\Delta t_i}\right)^2+\left(\frac{\Delta y_i}{\Delta t_i}\right)^2\right]\Delta t_i}\)
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\(\displaystyle \sqrt{\left(\frac{\Delta x_i}{\Delta t_i}\right)^2+\left(\frac{\Delta y_i}{\Delta t_i}\right)^2}\Delta t_i\)
(c)
Finally, weβll want to increase \(N\) from \(3\) so that it limits to \(\infty\text{.}\) What can we conclude when that happens?
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Each segment is infinitely small.
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\(\displaystyle \Delta x_i\to 0\)
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\(\displaystyle \frac{\Delta x_i}{\Delta t_i}\to\frac{dx}{dt}\)
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All of the above.
Observation 7.3.6.
Put together, and limiting the subdivisions of the curve \(N\to \infty\text{,}\) we obtain the Riemann sum
\begin{equation*}
\lim_{N\to\infty}\sum_{i=1}^N \sqrt{\left(\frac{\Delta x_i}{\Delta t_i}\right)^2+\left(\frac{\Delta y_i}{\Delta t_i}\right)^2}\Delta t_i\text{.}
\end{equation*}
Thus arclength along a parametric curve from \(a\leq t\leq b\) may be calculated by using the corresponding definite integral
\begin{equation*}
\int_{t=a}^{t=b} \sqrt{\left(\frac{dx}{dt}\right)^2+\left(\frac{dy}{dt}\right)^2}dt\text{.}
\end{equation*}
Activity 7.3.7.
Letβs gain confidence in the arclength formula
\begin{equation*}
\int_{t=a}^{t=b} \sqrt{\left(\frac{dx}{dt}\right)^2+\left(\frac{dy}{dt}\right)^2}dt
\end{equation*}
by checking to make sure it matches the distance formula for line segments.
The parametric equations \(x=3t-1\) and \(y=2-4t\) for \(1\leq t\leq 3\) represent the segment of the line \(y=-\frac{4}{3}x-\frac{2}{3}\) connecting \((2,-2)\) to \((8,-10)\text{.}\)
(a)
Find \(dx/dt\) and \(dy/dt\text{,}\) and substitute them into the formula above along with \(a=1\) and \(b=3\text{.}\)
(b)
Show that the value of this formula is \(10\text{.}\)
(c)
Show that the length of the line segment connecting \((2,-2)\) to \((8,-10)\) is \(10\) by applying the distance formula directly instead.
Activity 7.3.8.
For each of these parametric equations, use
\begin{equation*}
\int_{t=a}^{t=b} \sqrt{\left(\frac{dx}{dt}\right)^2+\left(\frac{dy}{dt}\right)^2}dt
\end{equation*}
to write a definite integral that computes the given length. (Do not evaluate the integral.)
(a)
(b)
(c)
Activity 7.3.9.
Letβs see how to modify \(\int_{t=a}^{t=b} \sqrt{\left(\frac{dx}{dt}\right)^2+\left(\frac{dy}{dt}\right)^2}dt\) to produce the arclength of the graph of a function \(y=f(x)\text{.}\)
(a)
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\(\displaystyle dx\)
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\(\displaystyle dt\)
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\(\displaystyle 1\)
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\(\displaystyle 0\)
(b)
(c)
Write a modified, simplified formula for \(\int_{t=a}^{t=b} \sqrt{\left(\frac{dx}{dt}\right)^2+\left(\frac{dy}{dt}\right)^2}dt\) with \(t\) replaced with \(x\text{.}\)
Subsection 7.3.2 Videos
Subsection 7.3.3 Exercises
Exercises available at
https://tbil.org/preview/calculus/exercises/#/bank/CO3/
