Skip to main content
Ch. 5 - Complex Numbers, Polar Coordinates and Parametric Equations
Blitzer - Trigonometry 3rd Edition
Blitzer3rd EditionTrigonometryISBN: 9780137316601Not the one you use?Change textbook
All textbooksBlitzer 3rd EditionCh. 5 - Complex Numbers, Polar Coordinates and Parametric EquationsProblem 9
Chapter 5, Problem 9

Test for symmetry with respect to a. the polar axis. b. the line θ = π/2. c. the pole. r = 4 + 3 cos θ

Verified step by step guidance
1
Recall the tests for symmetry in polar coordinates: - Symmetry about the polar axis (the horizontal axis) means that if \((r, \theta)\) is on the graph, then \((r, -\theta)\) is also on the graph. - Symmetry about the line \(\theta = \frac{\pi}{2}\) means that if \((r, \theta)\) is on the graph, then \((r, \pi - \theta)\) is also on the graph. - Symmetry about the pole (origin) means that if \((r, \theta)\) is on the graph, then \((-r, \theta)\) or equivalently \((r, \theta + \pi)\) is also on the graph.
To test symmetry about the polar axis, replace \(\theta\) with \(-\theta\) in the equation and check if the equation remains unchanged. For the given equation: \(r = 4 + 3 \cos \theta\) Replace \(\theta\) with \(-\theta\): \(r = 4 + 3 \cos(-\theta)\)
Use the even property of cosine, which states \(\cos(-\theta) = \cos \theta\), so the equation becomes: \(r = 4 + 3 \cos \theta\) Since this is the same as the original equation, the graph is symmetric about the polar axis.
To test symmetry about the line \(\theta = \frac{\pi}{2}\), replace \(\theta\) with \(\pi - \theta\) in the equation and check if the equation remains unchanged: \(r = 4 + 3 \cos(\pi - \theta)\)
Use the identity \(\cos(\pi - \theta) = -\cos \theta\), so the equation becomes: \(r = 4 - 3 \cos \theta\) Since this is not the same as the original equation, the graph is not symmetric about the line \(\theta = \frac{\pi}{2}\).

Verified video answer for a similar problem:

This video solution was recommended by our tutors as helpful for the problem above.
Video duration:
5m
Was this helpful?

Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Symmetry with Respect to the Polar Axis

Symmetry about the polar axis means the graph remains unchanged when θ is replaced by -θ. To test this, substitute -θ into the polar equation and check if the resulting equation is equivalent to the original. This reflects symmetry across the horizontal axis in polar coordinates.
Recommended video:
05:32
Intro to Polar Coordinates

Symmetry with Respect to the Line θ = π/2

Symmetry about the line θ = π/2 occurs if replacing θ by π - θ yields an equivalent equation. This tests whether the graph is mirrored across the vertical line θ = π/2 in the polar plane. It helps identify vertical symmetry in polar graphs.
Recommended video:
2:22
Cardioids Example 1

Symmetry with Respect to the Pole

Symmetry about the pole (origin) means the graph is unchanged when (r, θ) is replaced by (-r, θ) or equivalently (r, θ + π). Testing this involves checking if r(θ) = -r(θ + π) or if the equation remains valid under these transformations, indicating origin symmetry.
Recommended video:
2:22
Cardioids Example 1
Related Practice
Textbook Question

Perform the indicated operations and write the result in standard form. (−2 + √−100)²

Textbook Question

Indicate if the point with the given polar coordinates is represented by A, B, C, or D on the graph. (−3, −3π/4)

Textbook Question

Plot each complex number and find its absolute value. z = −3 + 4i

1
views
Textbook Question

Use a polar coordinate system like the one shown for Exercises 1–10 to plot each point with the given polar coordinates. (2, 45°)

Textbook Question

In Exercises 9–20, find each product and write the result in standard form. −3i(7i − 5)

Textbook Question

Perform the indicated operations and write the result in standard form. (4 + √−8 )/ 2