Textbook Question
Without calculating derivatives, determine the slopes of each of the lines tangent to the curve r=8 cos θ−4 at the origin.
Ch.12 - Parametric and Polar Curves
Briggs3rd EditionCalculus: Early TranscendentalsISBN: 9780136847243
Not the one you use?Change textbookSelect a different textbook
Table of contents
- Ch. 1 - Functions210
- Ch. 2 - Limits371
- Ch. 3 - Derivatives633
- Ch. 4 - Applications of the Derivative412
- Ch. 5 - Integration328
- Ch. 6 - Applications of Integration331
- Ch. 7 - Logarithmic, Exponential Functions, and Hyperbolic Functions177
- Ch. 8 - Integration Techniques394
- Ch. 9 - Differential Equations179
- Ch. 10 - Sequences and Infinite Series339
- Ch. 11 - Power Series218
- Ch.12 - Parametric and Polar Curves215
Briggs3rd EditionCalculus: Early TranscendentalsISBN: 9780136847243Not the one you use?Change textbook
Chapter 12, Problem 12.1.55
53–56. Circular motion Find parametric equations that describe the circular path of the following objects. For Exercises 53–55, assume (x, y) denotes the position of the object relative to the origin at the center of the circle. Use the units of time specified in the problem. There are many ways to describe any circle.
A bicyclist rides counterclockwise with constant speed around a circular velodrome track with a radius of 50 m, completing one lap in 24 seconds.
Verified step by step guidance1
Identify the key parameters of the circular motion: the radius \(r = 50\) meters, and the period \(T = 24\) seconds, which is the time to complete one full lap around the circle.
Recall that the parametric equations for circular motion centered at the origin with radius \(r\) and angular position \(\theta(t)\) are given by:
\(x(t) = r \cos(\theta(t))\),
\(y(t) = r \sin(\theta(t))\).
Determine the angular velocity \(\omega\), which is the rate of change of the angle with respect to time. Since one full lap corresponds to an angle of \(2\pi\) radians completed in \(T\) seconds, calculate
\(\omega = \frac{2\pi}{T} = \frac{2\pi}{24}\) radians per second.
Express the angle \(\theta(t)\) as a function of time using the angular velocity:
\(\theta(t) = \omega t = \frac{2\pi}{24} t\).
Write the final parametric equations for the bicyclist's position as functions of time:
\(x(t) = 50 \cos\left(\frac{2\pi}{24} t\right)\),
\(y(t) = 50 \sin\left(\frac{2\pi}{24} t\right)\).
Verified video answer for a similar problem:
This video solution was recommended by our tutors as helpful for the problem above.
Video duration:
3mWas this helpful?
Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Parametric Equations of Circular Motion
Parametric equations express the coordinates of a point on a circle as functions of time, typically using sine and cosine functions. For a circle of radius r centered at the origin, the position (x, y) can be described as x = r cos(θ(t)) and y = r sin(θ(t)), where θ(t) is the angle parameter changing over time.
Recommended video:
Guided course
08:02
Parameterizing Equations
Angular Velocity and Period
Angular velocity (ω) measures how fast an object rotates around a circle, defined as the angle covered per unit time. It relates to the period (T), the time for one full revolution, by ω = 2π / T. Knowing the period allows calculation of ω, which is essential for defining θ(t) = ωt in parametric equations.
Recommended video:
06:29Derivatives Applied To Velocity
Direction of Motion and Orientation
The direction of motion (clockwise or counterclockwise) affects the sign and form of the parametric equations. Counterclockwise motion is typically represented by increasing θ(t) over time, using positive angular velocity, ensuring the sine and cosine functions trace the circle in the correct orientation.
Recommended video:
05:21Finding Limits by Direct Substitution
Related Practice
Textbook Question
13–30. Graphing conic sections Determine whether the following equations describe a parabola, an ellipse, or a hyperbola, and then sketch a graph of the curve. For each parabola, specify the location of the focus and the equation of the directrix; for each ellipse, label the coordinates of the vertices and foci, and find the lengths of the major and minor axes; for each hyperbola, label the coordinates of the vertices and foci, and find the equations of the asymptotes.
x²/9 + y²/4 = 1
Textbook Question
{Use of Tech} Implicit function graph Explain and carry out a method for graphing the curve x = 1 + cos² y − sin² y using parametric equations and a graphing utility.
Textbook Question
Express the polar equation r=f(θ) in parametric form in Cartesian coordinates, where θ is the parameter.
Textbook Question
Tangent line at the origin Find the polar equation of the line tangent to the polar curve r=4cosθ at the origin. Explain why the slope of this line is undefined.
Textbook Question
15–30. Working with parametric equations Consider the following parametric equations.
a. Eliminate the parameter to obtain an equation in x and y.
b. Describe the curve and indicate the positive orientation.
x = 8 + 2t, y = 1; −∞ < t < ∞