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APEX Calculus

Section 10.3 Calculus and Parametric Equations

The previous section defined curves based on parametric equations. In this section we’ll employ the techniques of calculus to study these curves.
We are still interested in lines tangent to points on a curve. They describe how the \(y\)-values are changing with respect to the \(x\)-values, they are useful in making approximations, and they indicate instantaneous direction of travel.
Figure 10.3.1. Video introduction to Section 10.3
The slope of the tangent line is still \(\frac{dy}{dx}\text{,}\) and the Chain Rule allows us to calculate this in the context of parametric equations. If \(x=f(t)\) and \(y=g(t)\text{,}\) the Chain Rule states that
\begin{equation*} \frac{dy}{dt} = \frac{dy}{dx}\cdot\frac{dx}{dt}\text{.} \end{equation*}
Solving for \(\frac{dy}{dx}\text{,}\) we get
\begin{equation*} \frac{dy}{dx} = \frac{dy}{dt}\Bigg/\frac{dx}{dt} = \frac{g'(t)}{\fp(t)}\text{,} \end{equation*}
provided that \(\fp(t)\neq 0\text{.}\) This is important so we label it a Key Idea.

Key Idea 10.3.2. Finding \(\frac{dy}{dx}\) with Parametric Equations.

Let \(x=f(t)\) and \(y=g(t)\text{,}\) where \(f\) and \(g\) are differentiable on some open interval \(I\) and \(\fp(t)\neq 0\) on \(I\text{.}\) Then
\begin{equation*} \frac{dy}{dx} = \frac{g'(t)}{\fp(t)}\text{.} \end{equation*}
We use this to define the tangent line.

Definition 10.3.3. Tangent and Normal Lines.

Let a curve \(C\) be parametrized by \(x=f(t)\) and \(y=g(t)\text{,}\) where \(f\) and \(g\) are differentiable functions on some interval \(I\) containing \(t=t_0\text{.}\) The tangent line to \(C\) at \(t=t_0\) is the line through \(\big(f(t_0),g(t_0)\big)\) with slope \(m=g'(t_0)/\fp(t_0)\text{,}\) provided \(\fp(t_0)\neq 0\text{.}\)
The normal line to \(C\) at \(t=t_0\) is the line through \(\big(f(t_0),g(t_0)\big)\) with slope \(m=-\fp(t_0)/g'(t_0)\text{,}\) provided \(g'(t_0)\neq 0\text{.}\)
The definition leaves two special cases to consider. When the tangent line is horizontal, the normal line is undefined by the above definition as \(g'(t_0)=0\text{.}\) Likewise, when the normal line is horizontal, the tangent line is undefined. It seems reasonable that these lines be defined (one can draw a line tangent to the “right side” of a circle, for instance), so we add the following to the above definition.
  1. If the tangent line at \(t=t_0\) has a slope of 0, the normal line to \(C\) at \(t=t_0\) is the line \(x=f(t_0)\text{.}\)
  2. If the normal line at \(t=t_0\) has a slope of 0, the tangent line to \(C\) at \(t=t_0\) is the line \(x=f(t_0)\text{.}\)

Example 10.3.4. Tangent and Normal Lines to Curves.

Let \(x=5t^2-6t+4\) and \(y=t^2+6t-1\text{,}\) and let \(C\) be the curve defined by these equations.
  1. Find the equations of the tangent and normal lines to \(C\) at \(t=3\text{.}\)
  2. Find where \(C\) has vertical and horizontal tangent lines.
Solution 1.
  1. We start by computing \(\fp(t) = 10t-6\) and \(g'(t) =2t+6\text{.}\) Thus
    \begin{equation*} \frac{dy}{dx} = \frac{2t+6}{10t-6}\text{.} \end{equation*}
    Make note of something that might seem unusual: \(\frac{dy}{dx}\) is a function of \(t\text{,}\) not \(x\text{.}\) Just as points on the curve are found in terms of \(t\text{,}\) so are the slopes of the tangent lines. The point on \(C\) at \(t=3\) is \((31,26)\text{.}\) The slope of the tangent line is \(m=1/2\) and the slope of the normal line is \(m=-2\text{.}\) Thus,
    • the equation of the tangent line is \(\ds y=\frac12(x-31)+26\text{,}\) and
    • the equation of the normal line is \(\ds y=-2(x-31)+26\text{.}\)
    This is illustrated in Figure 10.3.5.
    Plot of a parametric curve and its tangent and normal lines at one point.
    The curve \(x=5t^2-6t+4, y=t^2+6t-1\) is shown. The shape of the curve is that of a distored parabola, opening to the right from a vertex near \((2,3)\text{.}\) (The precise location is \(\left(\frac{11}{5},\frac{74}{25}\right)\text{.}\)) The curve begins below the \(x\) axis, traveling left until it reaches the vertex, after which it continues up and to the right.
    At the point \((31,26)\text{,}\) the tangent and normal lines to the curve are shown. The tangent line has a positive slope, while the normal line has a negative slope, and as expected, the two lines are perpendicular.
    Figure 10.3.5. Graphing tangent and normal lines in Example 10.3.4
  2. To find where \(C\) has a horizontal tangent line, we set \(\frac{dy}{dx}=0\) and solve for \(t\text{.}\) In this case, this amounts to setting \(g'(t)=0\) and solving for \(t\) (and making sure that \(\fp(t)\neq 0\)).
    \begin{equation*} g'(t)=0 \Rightarrow 2t+6=0 \Rightarrow t=-3\text{.} \end{equation*}
    The point on \(C\) corresponding to \(t=-3\) is \((67,-10)\text{;}\) the tangent line at that point is horizontal (hence with equation \(y=-10\)). To find where \(C\) has a vertical tangent line, we find where it has a horizontal normal line, and set \(-\frac{\fp(t)}{g'(t)}=0\text{.}\) This amounts to setting \(\fp(t)=0\) and solving for \(t\) (and making sure that \(g'(t)\neq 0\)).
    \begin{equation*} \fp(t)=0 \Rightarrow 10t-6=0 \Rightarrow t=0.6\text{.} \end{equation*}
    The point on \(C\) corresponding to \(t=0.6\) is \((2.2,2.96)\text{.}\) The tangent line at that point is \(x=2.2\text{.}\) The points where the tangent lines are vertical and horizontal are indicated on the graph in Figure 10.3.5.
Solution 2. Video solution

Example 10.3.6. Tangent and Normal Lines to a Circle.

  1. Find where the unit circle, defined by \(x=\cos(t)\) and \(y=\sin(t)\) on \([0,2\pi]\text{,}\) has vertical and horizontal tangent lines.
  2. Find the equation of the normal line at \(t=t_0\text{.}\)
Solution 1.
  1. We compute the derivative following Key Idea 10.3.2:
    \begin{equation*} \frac{dy}{dx} = \frac{g'(t)}{\fp(t)} = -\frac{\cos(t) }{\sin(t) }\text{.} \end{equation*}
    The derivative is \(0\) when \(\cos(t) = 0\text{;}\) that is, when \(t=\pi/2,\, 3\pi/2\text{.}\) These are the points \((0,1)\) and \((0,-1)\) on the circle. The normal line is horizontal (and hence, the tangent line is vertical) when \(\sin(t) =0\text{;}\) that is, when \(t= 0,\,\pi,\,2\pi\text{,}\) corresponding to the points \((-1,0)\) and \((0,1)\) on the circle. These results should make intuitive sense.
  2. The slope of the normal line at \(t=t_0\) is \(\ds m=\frac{\sin(t_0) }{\cos(t_0) } = \tan(t_0)\text{.}\) This normal line goes through the point \((\cos(t_0) ,\sin(t_0) )\text{,}\) giving the line
    \begin{align*} y \amp =\frac{\sin(t_0) }{\cos(t_0) }(x-\cos(t_0) ) + \sin(t_0)\\ \amp = (\tan(t_0) )x\text{,} \end{align*}
    as long as \(\cos(t_0) \neq 0\text{.}\) It is an important fact to recognize that the normal lines to a circle pass through its center, as illustrated in Figure 10.3.7. Stated in another way, any line that passes through the center of a circle intersects the circle at right angles.
    Sketch of the unit circle and one normal line, which passes through the circle’s center.
    A sketch of the unit circle is shown. At a point on the circle in the first quadrant (corresponding to an angle that appears to be slightly more than \(\pi/3\)), a normal line is drawn.
    The normal line passes through the center of the circle, illustrating the conclusion of this example.
    Figure 10.3.7. Illustrating how a circle’s normal lines pass through its center
Solution 2. Video solution

Example 10.3.8. Tangent lines when \(\frac{dy}{dx}\) is not defined.

Find the equation of the tangent line to the astroid \(x=\cos^3(t)\text{,}\) \(y=\sin^3(t)\) at \(t=0\text{,}\) shown in Figure 10.3.9.
Graph of an astroid.
Graph of the astroid curve \(x^{2/3}+y^{2/3}=1\text{.}\) It has cusps at the vertices \((1,0),(0,1),(-1,0)\) and \((0,-1)\text{.}\)
Figure 10.3.9. A graph of an astroid
Solution 1.
We start by finding \(x'(t)\) and \(y'(t)\text{:}\)
\begin{equation*} x'(t) = -3\sin(t) \cos^2(t) , \qquad y'(t) = 3\cos(t) \sin^2(t)\text{.} \end{equation*}
Note that both of these are 0 at \(t=0\text{;}\) the curve is not smooth at \(t=0\) forming a cusp on the graph. Evaluating \(\frac{dy}{dx}\) at this point returns the indeterminate form of “0/0”.
We can, however, examine the slopes of tangent lines near \(t=0\text{,}\) and take the limit as \(t\to 0\text{.}\)
\begin{align*} \lim_{t\to0} \frac{y'(t)}{x'(t)} \amp =\lim_{t\to0} \frac{3\cos(t) \sin^2(t) }{-3\sin(t) \cos^2(t) } \text{ (We can cancel as \(t\neq 0\).) }\\ \amp = \lim_{t\to0} -\frac{\sin(t) }{\cos(t) }\\ \amp = 0\text{.} \end{align*}
We have accomplished something significant. When the derivative \(\frac{dy}{dx}\) returns an indeterminate form at \(t=t_0\text{,}\) we can define its value by setting it to be \(\lim\limits_{t\to t_0}\)\(\frac{dy}{dx}\text{,}\) if that limit exists. This allows us to find slopes of tangent lines at cusps, which can be very beneficial.
We found the slope of the tangent line at \(t=0\) to be 0; therefore the tangent line is \(y=0\text{,}\) the \(x\)-axis.
Solution 2. Video solution

Subsection 10.3.1 Concavity

We continue to analyze curves in the plane by considering their concavity; that is, we are interested in \(\frac{d^2y}{dx^2}\text{,}\) “the second derivative of \(y\) with respect to \(x\text{.}\)” To find this, we need to find the derivative of \(\frac{dy}{dx}\) with respect to \(x\text{;}\) that is,
\begin{equation*} \frac{d^2y}{dx^2}=\frac{d}{dx}\left[\frac{dy}{dx}\right]\text{,} \end{equation*}
but recall that \(\frac{dy}{dx}\) is a function of \(t\text{,}\) not \(x\text{,}\) making this computation not straightforward.
To make the upcoming notation a bit simpler, let \(h(t) = \frac{dy}{dx}\text{.}\) We want \(\frac{d}{dx}[h(t)]\text{;}\) that is, we want \(\frac{dh}{dx}\text{.}\) We again appeal to the Chain Rule. Note:
\begin{equation*} \frac{dh}{dt} = \frac{dh}{dx}\cdot\frac{dx}{dt} \Rightarrow \frac{dh}{dx} = \frac{dh}{dt}\Bigg/\frac{dx}{dt}\text{.} \end{equation*}
In words, to find \(\frac{d^2y}{dx^2}\text{,}\) we first take the derivative of \(\frac{dy}{dx}\) with respect to \(t\), then divide by \(x'(t)\text{.}\) We restate this as a Key Idea.

Key Idea 10.3.10. Finding \(\frac{d^2y}{dx^2}\) with Parametric Equations.

Let \(x=f(t)\) and \(y=g(t)\) be twice differentiable functions on an open interval \(I\text{,}\) where \(\fp(t)\neq 0\) on \(I\text{.}\) Then
\begin{equation*} \frac{d^2y}{dx^2} = \frac{d}{dt}\left[\frac{dy}{dx}\right]\Bigg/\frac{dx}{dt} = \frac{d}{dt}\left[\frac{dy}{dx}\right]\Bigg/\fp(t)\text{.} \end{equation*}
Examples will help us understand this Key Idea.

Example 10.3.11. Concavity of Plane Curves.

Let \(x=5t^2-6t+4\) and \(y=t^2+6t-1\) as in Example 10.3.4. Determine the \(t\)-intervals on which the graph is concave up/down.
Solution 1.
Concavity is determined by the second derivative of \(y\) with respect to \(x\text{,}\) \(\frac{d^2y}{dx^2}\text{,}\) so we compute that here following Key Idea 10.3.10.
In Example 10.3.4, we found \(\ds\frac{dy}{dx} = \frac{2t+6}{10t-6}\) and \(\fp(t) = 10t-6\text{.}\) So:
\begin{align*} \frac{d^2y}{dx^2} \amp = \frac{d}{dt}\left[\frac{2t+6}{10t-6}\right]\Bigg/(10t-6)\\ \amp = -\frac{72}{(10t-6)^2}\Bigg/(10t-6)\\ \amp = -\frac{72}{(10t-6)^3}\\ \amp = -\frac{9}{(5t-3)^3} \end{align*}
Sketch of a parametric curve illustrating concavity.
The curve shown is the same distorted parabola from Example 10.3.4, but without the tangent and normal lines.
Below the vertex, which corresponds to \(t=3/5\text{,}\) the curve is concave up, and there is a label on the curve indicating that for \(t\lt 3/5\text{,}\) the curve is concave up. Above the vertex, the curve is concave down, and there is a label on the curve indicating that for \(t\gt 3/5\text{,}\) the curve is concave down.
Figure 10.3.12. Graphing the parametric equations in Example 10.3.11 to demonstrate concavity
The graph of the parametric functions is concave up when \(\frac{d^2y}{dx^2} \gt 0\) and concave down when \(\frac{d^2y}{dx^2} \lt 0\text{.}\) We determine the intervals when the second derivative is greater/less than 0 by first finding when it is 0 or undefined.
As the numerator of \(\ds -\frac{9}{(5t-3)^3}\) is never 0, \(\frac{d^2y}{dx^2} \neq 0\) for all \(t\text{.}\) It is undefined when \(5t-3=0\text{;}\) that is, when \(t= 3/5\text{.}\) Following the work established in Section 3.4, we look at values of \(t\) greater/less than \(3/5\) on a number line:
A number line for the sign of the second derivative in this example.
A number line is shown, on which the value \(3/5\) is marked. To the left of this point there is text indicating that \(\frac{d^2y}{dx^2}\gt 0\text{,}\) and that the curve is concave up. To the right of this point there is text indicating that \(\frac{d^2y}{dx^2}\lt 0\text{,}\) and that the curve is concave down.
Reviewing Example 10.3.4, we see that when \(t=3/5=0.6\text{,}\) the graph of the parametric equations has a vertical tangent line. This point is also a point of inflection for the graph, illustrated in Figure 10.3.12.
The video in Figure 10.3.13 shows how this information can be used to sketch the curve by hand.
Figure 10.3.13. Sketching the curve in Example 10.3.11
Solution 2. Video solution

Example 10.3.14. Concavity of Plane Curves.

Find the points of inflection of the graph of the parametric equations \(x=\sqrt{t}\text{,}\) \(y=\sin(t)\text{,}\) for \(0\leq t\leq 16\text{.}\)
Solution.
We need to compute \(\frac{dy}{dx}\) and \(\frac{d^2y}{dx^2}\text{.}\)
\begin{equation*} \frac{dy}{dx} = \frac{y'(t)}{x'(t)} = \frac{\cos(t) }{1/(2\sqrt{t})} = 2\sqrt{t}\cos(t)\text{.} \end{equation*}
\begin{equation*} \frac{d^2y}{dx^2} = \frac{\frac{d}{dt}\left[\frac{dy}{dx}\right]}{x'(t)} = \frac{\cos(t) /\sqrt{t}-2\sqrt{t}\sin(t) }{1/(2\sqrt{t})}=2\cos(t) -4t\sin(t)\text{.} \end{equation*}
The points of inflection are found by setting \(\frac{d^2y}{dx^2}=0\text{.}\) This is not trivial, as equations that mix polynomials and trigonometric functions generally do not have “nice” solutions.
In Figure 10.3.15.(a) we see a plot of the second derivative. It shows that it has zeros at approximately \(t=0.5,\,3.5,\,6.5,\,9.5,\,12.5\) and \(16\text{.}\) These approximations are not very good, made only by looking at the graph. Newton’s Method provides more accurate approximations. Accurate to 2 decimal places, we have:
\begin{equation*} t=0.65,\,3.29,\,6.36,\,9.48,\,12.61\,\text{ and } \,15.74\text{.} \end{equation*}
The corresponding points have been plotted on the graph of the parametric equations in Figure 10.3.15.(b). Note how most occur near the \(x\)-axis, but not exactly on the axis.
Graph of the second derivative is a sinusoid with increasing amplitude.
The image shows the graph \(y = 2\cos(t)-4t\sin(t)\text{,}\) which is a graph of \(\frac{d^2y}{dx^2}\text{.}\) The curve is sinusoidal, but with an amplitude that increases as \(t\) increases. The graph allows us to estimate the values of \(t\) where the second derivative is zero.
(a)
Graph of the parametric curve in this example, with points of inflection marked.
The graph shows a curve that appears to be sinusoidal, but with a frequency that increases with \(x\text{.}\) On the graph are several marked points, indicating where the inflection points occur.
(b)
Figure 10.3.15. In (a), a graph of \(\frac{d^2y}{dx^2}\text{,}\) showing where it is approximately 0. In (b), graph of the parametric equations in Example 10.3.14 along with the points of inflection

Subsection 10.3.2 Arc Length

We continue our study of the features of the graphs of parametric equations by computing their arc length.
Figure 10.3.16. Video introduction to arc length for parametric curves
Recall in Section 7.4 we found the arc length of the graph of a function, from \(x=a\) to \(x=b\text{,}\) to be
\begin{equation*} L = \int_a^b\sqrt{1+\left(\frac{dy}{dx}\right)^2}\, dx\text{.} \end{equation*}
We can use this equation and convert it to the parametric equation context. Letting \(x=f(t)\) and \(y=g(t)\text{,}\) we know that \(\frac{dy}{dx} = g'(t)/\fp(t)\text{.}\) It will also be useful to calculate the differential of \(x\text{:}\)
\begin{equation*} dx = \fp(t)dt \qquad \Rightarrow \qquad dt = \frac{1}{\fp(t)}\cdot dx\text{.} \end{equation*}
Starting with the arc length formula above, consider:
\begin{align*} L \amp = \int_a^b\sqrt{1+\left(\frac{dy}{dx}\right)^2}\, dx\\ \amp = \int_a^b \sqrt{1+\frac{g'(t)^2}{\fp(t)^2}}\, dx.\\ \end{align*}
Factor out the \(\fp(t)^2\text{:}\)
\begin{align*} \amp = \int_a^b \sqrt{\fp(t)^2+g'(t)^2}\cdot\underbrace{\frac1{\fp(t)}\, dx}_{=dt}\\ \amp = \int_{t_1}^{t_2} \sqrt{\fp(t)^2+g'(t)^2}\, dt\text{.} \end{align*}
Note the new bounds (no longer “\(x\)” bounds, but “\(t\)” bounds). They are found by finding \(t_1\) and \(t_2\) such that \(a= f(t_1)\) and \(b=f(t_2)\text{.}\) This formula is important, so we restate it as a theorem.
As before, these integrals are often not easy to compute. We start with a simple example, then give another where we approximate the solution.

Example 10.3.18. Arc Length of a Circle.

Find the arc length of the circle parametrized by \(x=3\cos(t)\text{,}\) \(y=3\sin(t)\) on \([0,3\pi/2]\text{.}\)
Solution 1.
By direct application of Theorem 10.3.17, we have
\begin{align*} L \amp = \int_0^{3\pi/2} \sqrt{(-3\sin(t) )^2 +(3\cos(t) )^2} \, dt.\\ \end{align*}
Apply the Pythagorean Theorem.
\begin{align*} \amp = \int_0^{3\pi/2} 3 \, dt\\ \amp = 3t\Big|_0^{3\pi/2} = 9\pi/2\text{.} \end{align*}
This should make sense; we know from geometry that the circumference of a circle with radius 3 is \(6\pi\text{;}\) since we are finding the arc length of \(3/4\) of a circle, the arc length is \(3/4\cdot 6\pi = 9\pi/2\text{.}\)
Solution 2. Video solution

Example 10.3.19. Arc Length of a Parametric Curve.

The graph of the parametric equations \(x=t(t^2-1)\text{,}\) \(y=t^2-1\) crosses itself as shown in Figure 10.3.20, forming a “teardrop.” Find the arc length of the teardrop.
Graph of a "teardrop" curve that intersects itself at the origin.
The curve given by \(x=t(t^2-1), y=t^2-1\) forms a “teardrop” shape. The curve crosses itself at the origin, and the teardrop portion of the graph lies below the \(x\) axis.
Figure 10.3.20. A graph of the parametric equations in Example 10.3.19, where the arc length of the teardrop is calculated
Solution 1.
We can see by the parametrizations of \(x\) and \(y\) that when \(t=\pm 1\text{,}\) \(x=0\) and \(y=0\text{.}\) This means we’ll integrate from \(t=-1\) to \(t=1\text{.}\) Applying Theorem 10.3.17, we have
\begin{align*} L \amp = \int_{-1}^1\sqrt{(3t^2-1)^2+(2t)^2}\, dt\\ \amp = \int_{-1}^1 \sqrt{9t^4-2t^2+1} \, dt\text{.} \end{align*}
Unfortunately, the integrand does not have an antiderivative expressible by elementary functions. We turn to numerical integration to approximate its value. Using 4 subintervals, Simpson’s Rule approximates the value of the integral as \(2.65051\text{.}\) Using a computer, more subintervals are easy to employ, and \(n=20\) gives a value of \(2.71559\text{.}\) Increasing \(n\) shows that this value is stable and a good approximation of the actual value.
Solution 2. Video solution

Subsection 10.3.3 Surface Area of a Solid of Revolution

Related to the formula for finding arc length is the formula for finding surface area. We can adapt the formula found in Theorem 7.4.13 from Section 7.4 in a similar way as done to produce the formula for arc length done before.

Example 10.3.22. Surface Area of a Solid of Revolution.

Consider the teardrop shape formed by the parametric equations \(x=t(t^2-1)\text{,}\) \(y=t^2-1\) as seen in Example 10.3.19. Find the surface area if this shape is rotated about the \(x\)-axis, as shown in Figure 10.3.23.
Figure 10.3.23. Rotating a teardrop shape about the \(x\)-axis in Example 10.3.22
Solution.
The teardrop shape is formed between \(t=-1\) and \(t=1\text{.}\) Using Theorem 10.3.21, we see we need for \(g(t)\geq 0\) on \([-1,1]\text{,}\) and this is not the case. To fix this, we simplify replace \(g(t)\) with \(-g(t)\text{,}\) which flips the whole graph about the \(x\)-axis (and does not change the surface area of the resulting solid). The surface area is:
\begin{align*} \text{ Area } \,S \amp = 2\pi\int_{-1}^1 (1-t^2)\sqrt{(3t^2-1)^2+(2t)^2}\, dt\\ \amp = 2\pi\int_{-1}^1 (1-t^2)\sqrt{9t^4-2t^2+1} \, dt\text{.} \end{align*}
Once again we arrive at an integral that we cannot compute in terms of elementary functions. Using Simpson’s Rule with \(n=20\text{,}\) we find the area to be \(S=9.44\text{.}\) Using larger values of \(n\) shows this is accurate to 2 places after the decimal.
After defining a new way of creating curves in the plane, in this section we have applied calculus techniques to the parametric equation defining these curves to study their properties. In the next section, we define another way of forming curves in the plane. To do so, we create a new coordinate system, called polar coordinates, that identifies points in the plane in a manner different than from measuring distances from the \(y\)- and \(x\)- axes.

Exercises 10.3.4 Exercises

Terms and Concepts

1.
True or False? Given parametric equations \(x=f(t)\) and \(y=g(t)\text{,}\) \(\lz{y}{x} = \fp(t)/g'(t)\text{,}\) as long as \(g'(t) \neq 0\text{.}\)
  • True
  • False
2.
Given parametric equations \(x=f(t)\) and \(y=g(t)\text{,}\) the derivative \(\frac{dy}{dx}\) as given in Key Idea 10.3.2 is a function of ?
3.
True or False? Given parametric equations \(x=f(t)\) and \(y=g(t)\text{,}\) to find \(\lzn{2}{y}{x}\text{,}\) one simply computes \(\lzoo{t}{\lz{y}{x}}\text{.}\)
  • True
  • False
4.
True or False? If \(\lz{y}{x}=0\) at \(t=t_0\text{,}\) then the normal line to the curve at \(t=t_0\) is a vertical line.
  • True
  • False

Problems

Exercise Group.
In the following exercises, parametric equations for a curve are given.
  1. Find \(\ds\frac{dy}{dx}\text{.}\)
  2. Find the equations of the tangent and normal line(s) at the point(s) given.
  3. Sketch the graph of the parametric functions along with the found tangent and normal lines.
5.
\(x=t\text{,}\) \(y=t^2\text{;}\)\(t=1\)
6.
\(x=\sqrt{t}\text{,}\) \(y=5t+2\text{;}\)\(t=4\)
7.
\(x=t^2-t\text{,}\) \(y=t^2+t\text{;}\)\(t=1\)
8.
\(x=t^2-1\text{,}\) \(y=t^3-t\text{;}\)\(t=0\) and \(t=1\)
9.
\(x=\sec(t)\text{,}\) \(y=\tan(t)\) on \((-\pi/2,\pi/2)\text{;}\)\(t=\pi/4\)
10.
\(x=\cos(t)\text{,}\) \(y=\sin(2t)\) on \([0,2\pi]\text{;}\)\(t=\pi/4\)
11.
\(x=\cos(t) \sin(2t)\text{,}\) \(y=\sin(t) \sin(2t)\) on \([0,2\pi]\text{;}\) \(t=3\pi/4\)
12.
\(x=e^{t/10}\cos(t)\text{,}\) \(y=e^{t/10}\sin(t)\text{;}\) \(t=\pi/2\)
Exercise Group.
Find the \(t\)-values where the curve defined by the given parametric equations has a horizontal tangent line. Note: these are the same equations as in Exercises 5–12.
13.
\(x=t\text{,}\) \(y=t^2\)
14.
\(x=\sqrt{t}\text{,}\) \(y=5t+2\)
15.
\(x=t^2-t\text{,}\) \(y=t^2+t\)
16.
\(x=t^2-1\text{,}\) \(y=t^3-t\)
17.
\(x=\sec(t)\text{,}\) \(y=\tan(t)\) on \((-\pi/2,\pi/2)\)
18.
\(x=\cos(t)\text{,}\) \(y=\sin(2t)\text{,}\) on \([0,2\pi)\)
19.
\(x=\cos(t) \sin(2t)\text{,}\) \(y=\sin(t) \sin(2t)\) on \([0,2\pi]\)
20.
\(x=e^{t/10}\cos(t)\text{,}\) \(y=e^{t/10}\sin(t)\)
Exercise Group.
Find the point \(t=t_0\) where the graph of the given parametric equations is not smooth, then find \(\lim\limits_{t\to t_0}\frac{dy}{dx}\text{.}\)
21.
\(x=\frac{1}{t^2+1}\text{,}\) \(y=t^3\)
22.
\(x=-t^3+7t^2-16t+13\text{,}\) \(y=t^3-5t^2+8t-2\)
23.
\(x=t^3-3t^2+3t-1\text{,}\)\(y=t^2-2t+1\)
24.
\(\ds x=\cos^2(t)\text{,}\)\(y=1-\sin^2(t)\)
Exercise Group.
For the given parametric equations for a curve, find \(\frac{d^2y}{dx^2}\text{,}\) then determine the intervals on which the graph of the curve is concave up/down. Note: these are the same equations as in Exercises 5–12.
25.
\(x=t\text{,}\)\(y=t^2\)
26.
\(x=\sqrt{t}\text{,}\)\(y=5t+2\)
27.
\(x=t^2-t\text{,}\) \(y=t^2+t\)
28.
\(x=t^2-1\text{,}\)\(y=t^3-t\)
29.
\(x=\sec(t)\text{,}\)\(y=\tan(t)\) on \((-\pi/2,\pi/2)\)
30.
\(x=\cos(t)\text{,}\) \(y=\sin(2t)\text{,}\) on \([0,2\pi)\)
31.
\(\ds x=\cos(t) \sin(2t)\text{,}\)\(y=\sin(t) \sin(2t)\) on \([-\pi/2,\pi/2]\)
32.
\(x=e^{t/10}\cos(t)\text{,}\)\(y=e^{t/10}\sin(t)\)
Exercise Group.
Find the arc length of the graph of the parametric equations on the given interval(s).
33.
\(x=-3\sin(2t)\text{,}\) \(y=3\cos(2t)\) on \([0,\pi]\)
34.
\(x=e^{t/10}\cos(t)\text{,}\) \(y=e^{t/10}\sin(t)\) on \([0,2\pi]\) and \([2\pi,4\pi]\text{.}\)
35.
\(x=5t+2\text{,}\) \(y=1-3t\) on \([-1,1]\)
36.
\(x=2t^{3/2}\text{,}\)\(y=3t\) on \([0,1]\)
Exercise Group.
In the following exercises, numerically approximate the given arc length.
37.
Approximate the arc length of one petal of the rose curve \(x=\cos(t) \cos(2t)\text{,}\)\(y=\sin(t) \cos(2t)\) using Simpson’s Rule and \(n=4\text{.}\)
38.
Approximate the arc length of the “bow tie curve” \(x=\cos(t)\text{,}\)\(y=\sin(2t)\) using Simpson’s Rule and \(n=6\text{.}\)
39.
Approximate the arc length of the parabola \(x=t^2-t\text{,}\)\(y=t^2+t\) on \([-1,1]\) using Simpson’s Rule and \(n=4\text{.}\)
40.
A common approximate of the circumference of an ellipse given by \(x=a\cos(t)\text{,}\)\(y=b\sin(t)\) is \(\ds C\approx 2\pi\sqrt{\frac{a^2+b^2}2}\text{.}\) Use this formula to approximate the circumference of \(x=5\cos(t)\text{,}\) \(y=3\sin(t)\) and compare this to the approximation given by Simpson’s Rule and \(n=6\text{.}\)
Exercise Group.
In the following exercises, a solid of revolution is described. Find or approximate its surface area as specified.
41.
Find the surface area of the sphere formed by rotating the circle \(x=2\cos(t)\text{,}\)\(y=2\sin(t)\) about:
(a)
The \(x\)-axis.
(b)
The \(y\)-axis.
42.
Find the surface area of the torus (or “donut”) formed by rotating the circle \(x=\cos(t) +2\text{,}\)\(y=\sin(t)\) about the \(y\)-axis.
43.
Approximate the surface area of the solid formed by rotating the “upper right half” of the bow tie curve \(x=\cos(t)\text{,}\)\(y=\sin(2t)\) on \([0,\pi/2]\) about the \(x\)-axis, using Simpson’s Rule and \(n=4\text{.}\)
44.
Approximate the surface area of the solid formed by rotating the one petal of the rose curve \(x=\cos(t) \cos(2t)\text{,}\)\(y=\sin(t) \cos(2t)\) on \([0,\pi/4]\) about the \(x\)-axis, using Simpson’s Rule and \(n=4\text{.}\)