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6.07 Graphing reciprocal trigonometric functions

Introduction

We explored the graphs of the basic trigonometric functions in lesson  6.04 Graphing sine and cosine functions  and lesson  6.06 Graphing tangent functions  . This lesson explores the key features of the reciprocal functions and how they relate to the unit circle.

Graphing reciprocal trigonometric functions

Recall that the cosecant function for the central angle, \theta, on the unit circle, is written as \csc \theta and it is defined by \csc \theta = \dfrac{1}{\sin \theta}. Similarly, the secant function is defined by \sec \theta = \dfrac{1}{\cos \theta}. Lastly, the cotangent function is defined by \cot \theta= \dfrac{1}{\tan \theta}.

Exploration

Explore the applet by checking the boxes.

Loading interactive...
  1. What do you notice about the graphs of cosecant and sine?
  2. What do you notice about the graphs of secant and cosine?
  3. What do you notice about the graphs of cotangent and tangent?

The reciprocal trigonometric functions are related to the exact values on the unit circle like the basic trigonometric functions are related to the unit circle, so the graphs of the reciprocal functions are also related to the graphs of the basic trigonometric functions.

\frac{1}{2}\pi
1\pi
\frac{3}{2}\pi
2\pi
x
-1
1
f \left(x \right)
f \left(x\right) = \csc x
\frac{1}{2}\pi
1\pi
\frac{3}{2}\pi
2\pi
x
-1
1
y
g \left(x \right) = \sin x graphed with f \left(x \right) = \csc x

Some of the key features of the cosecant function are as follows:

  • Domain: x \neq n \pi, n is any integer
  • Range: \left( -\infty, -1] \cup [1, \infty \right)
  • x-intercept: None
  • y-intercept: None
  • Period: 2 \pi
  • Amplitude: None
  • Midline: y=0
\frac{1}{2}\pi
1\pi
\frac{3}{2}\pi
2\pi
x
-1
1
f \left( x\right)
f \left(x\right) = \sec x
\frac{1}{2}\pi
1\pi
\frac{3}{2}\pi
2\pi
x
-1
1
y
g \left(x \right) = \cos x graphed with f\left(x\right) = \sec x

Some of the key features of the secant function are as follows:

  • Domain: x \neq \dfrac{\pi}{2} + n \pi, n is any integer
  • Range: \left( -\infty, -1] \cup [1, \infty \right)
  • x-intercept: None
  • y-intercept: y=1
  • Period: 2 \pi
  • Amplitude: None
  • Midline: y=0
\frac{1}{2}\pi
1\pi
\frac{3}{2}\pi
2\pi
x
-1
1
f \left(x \right)
f \left(x\right) = \cot x
\frac{1}{2}\pi
1\pi
\frac{3}{2}\pi
2\pi
x
-1
1
y
g \left(x \right) = \tan x graphed with f \left(x \right) = \cot x

Some of the key features of the cotangent function are as follows:

  • Domain: x \neq n \pi, n is any integer
  • Range: \left( -\infty, \infty \right)
  • x-intercept: x = \dfrac{\pi}{2} \pm n \pi, n is any integer
  • y-intercept: None
  • Period: \pi
  • Amplitude: None
  • Midline: y=0

Examples

Example 1

Sketch the graph of f \left( \theta \right) = \sec \theta on the interval \left[ -2 \pi, 2 \pi \right].

Worked Solution
Create a strategy

We can begin by graphing \cos \theta. Since \sec\theta=\dfrac{1}{\cos\theta}, the function f\left(\theta\right)=\sec\theta will have vertical asymptotes at the values of \theta that make \cos\theta=0.

We also know that the reciprocal of -1 is -1, and the reciprocal of 1 is 1. So, the values of theta that make \cos\theta=\pm 1 will also make \sec\theta=\pm 1.

Apply the idea

The asymptotes of the secant function occur at multiples of \dfrac{\pi}{2}, which is where the values of the cosine function approach and become equal to 0.

-2\pi
-\frac{3}{2}\pi
-1\pi
-\frac{1}{2}\pi
\frac{1}{2}\pi
1\pi
\frac{3}{2}\pi
2\pi
\theta
-2
-1
1
2
f \left( \theta \right)

Since secant is the reciprocal of cosine, the graph of secant will decrease over the intervals where the cosine function in increasing, and it will increase over the intervals where the cosine function is decreasing.

We can build the periodic function based on that information:

-2\pi
-\frac{3}{2}\pi
-1\pi
-\frac{1}{2}\pi
\frac{1}{2}\pi
1\pi
\frac{3}{2}\pi
2\pi
\theta
-2
-1
1
2
f \left( \theta \right)
Reflect and check

An alternate method of graphing the secant function is by building a table of values for y=\cos\theta, then finding the reciprocals of the values in the table. The reciprocals will be the outputs of the secant function since \sec\theta=\dfrac{1}{\cos\theta}.

\theta0\dfrac{\pi}{4}\dfrac{\pi}{2}\dfrac{3 \pi}{4}\pi\dfrac{5 \pi}{4}\dfrac{3 \pi}{2}\dfrac{7 \pi}{4}2 \pi
\cos \theta1\dfrac{\sqrt{2}}{2}0-\dfrac{\sqrt{2}}{2}-1-\dfrac{\sqrt{2}}{2}0\dfrac{\sqrt{2}}{2}1
\sec \theta1\sqrt{2}\text{undefined}-\sqrt{2}-1-\sqrt{2}\text{undefined}\sqrt{2}1

A calculator can be used to estimate the values with radicals to make graphing those points easier.

Example 2

Consider the function f \left(x\right) =\csc \left(3x\right).

a

State the equations of the asymptotes on the interval \left[0, 2\pi\right].

Worked Solution
Create a strategy

We know that the asymptotes of y=\csc x are at multiples of x=\pi. If we can identify how {f\left(x\right)=\csc\left(3x\right)} has been transformed from y=\csc x, then we can determine how the asymptotes have been affected.

Apply the idea

The given function is in the form f\left(x\right)=\csc\left(b\cdot x\right) where b=3 which means it has been horizontally compressed by a factor of \dfrac{1}{3}. This will affect the location of the asymptotes, causing them to occur at multiples of x=\dfrac{\pi}{3}.

On the interval \left[0,2\pi\right], the vertical asymptotes are located at x=0,\,\dfrac{\pi}{3},\,\dfrac{2\pi}{3},\,\pi,\,\dfrac{4\pi}{3},\,\dfrac{5\pi}{3},\,2\pi.

Reflect and check

We can check this answer by seeing if the stated values make \csc\left(3x\right) undefined or if they make \sin\left(3x\right)=0.

  • \sin\left(3\cdot 0\right)=\sin 0=0
  • \sin\left(3\cdot \frac{\pi}{3}\right)=\sin \pi=0
  • \sin\left(3\cdot \frac{2\pi}{3}\right)=\sin 2\pi=0
  • \sin\left(3\cdot \pi\right)=\sin 3\pi=0
  • \sin\left(3\cdot \frac{4\pi}{3}\right)=\sin 4\pi=0
  • \sin\left(3\cdot \frac{5\pi}{3}\right)=\sin 5\pi=0
  • \sin\left(3\cdot 2\pi\right)=\sin 6\pi=0
b

Sketch the graph of f \left(x\right) = \csc \left(3x\right).

Worked Solution
Create a strategy

In the previous part, we found that f\left(x\right)=\csc\left(3x\right) is the graph of y=\csc x that has been horizontally compressed by a factor of \dfrac{1}{3}, and its asymptotes occur at multiples of \dfrac{\pi}{3}.

Apply the idea

Graphing the parent function, y=\csc x, we have:

-\frac{3}{2}\pi
-1\pi
-\frac{1}{2}\pi
\frac{1}{2}\pi
1\pi
\frac{3}{2}\pi
x
-1
1
y

Compressing this by a factor of \dfrac{1}{3} results in:

-1\pi
-\frac{2}{3}\pi
-\frac{1}{3}\pi
\frac{1}{3}\pi
\frac{2}{3}\pi
1\pi
\theta
-5
-4
-3
-2
-1
1
2
3
4
5
f \left( \theta \right)
Reflect and check

Another way we could have graphed the function is by first graphing y=\sin\left(3x\right), then drawing the vertical asymptotes through the x-intercepts, and drawing the U-shaped curves tangent to the maxima and minima of sine but in between the drawn asymptotes.

-1\pi
-\frac{2}{3}\pi
-\frac{1}{3}\pi
\frac{1}{3}\pi
\frac{2}{3}\pi
1\pi
\theta
-5
-4
-3
-2
-1
1
2
3
4
5
f \left( \theta \right)
c

Explain whether the following key features are affected by the transformation:

  • Period
  • Midline
  • Domain
Worked Solution
Create a strategy

As we found in part (a), the function has been compressed horizontally by a factor of \dfrac{1}{3} which affected the asymptotes of the parent function y=\csc x. From this, we also know the period and domain have been affected by the transformation.

Apply the idea

Since the transformation only compressed the function horizontally, it had no effect on the midline. So, the midline remains at y=0.

Since the function was compressed by a factor of \dfrac{1}{3}, the period will be compressed by this factor. The period of the transformed function is \dfrac{2\pi}{3}.

Because the period and asymptotes of the function have been compressed, the domain has been affected too. The domain of the transformed function is x\neq \dfrac{n\pi}{3} where n is any integer.

Example 3

Consider the function f \left( \theta \right) = \cot \theta and the following table of values:

\theta0\dfrac{\pi}{4}\dfrac{\pi}{2}\dfrac{3 \pi}{4}\pi\dfrac{5 \pi}{4}\dfrac{3 \pi}{2}\dfrac{7 \pi}{4}2 \pi
\cos \theta1\dfrac{\sqrt{2}}{2}0-\dfrac{\sqrt{2}}{2}-1-\dfrac{\sqrt{2}}{2}0\dfrac{\sqrt{2}}{2}1
\sin \theta0\dfrac{\sqrt{2}}{2}1\dfrac{\sqrt{2}}{2}0-\dfrac{\sqrt{2}}{2}-1-\dfrac{\sqrt{2}}{2}0
\cot \theta
a

State the values of \theta on the interval \left[0, 2\pi\right] for which f \left( \theta \right) is undefined.

Worked Solution
Create a strategy

We know that f \left( \theta \right) = \cot \theta = \dfrac{\cos \theta}{\sin \theta}, so any values where \sin \theta = 0 are where f \left( \theta \right) is undefined.

Apply the idea

The values of \theta where f \left( \theta \right)=\cot\theta is undefined are \theta=0, \pi, and 2 \pi.

Reflect and check

We can also use the graph of y=\tan\theta to determine where the undefined values are.

-\frac{3}{2}\pi
-1\pi
-\frac{1}{2}\pi
\frac{1}{2}\pi
1\pi
\frac{3}{2}\pi
\theta
-1
1
y

Since \cot \theta=\dfrac{1}{\tan \theta}, we know that f\left(\theta\right)=\cot\theta will be undefined where \tan\theta=0, and \tan\theta=0 at multiples of \theta=\pi.

b

Sketch the graph of f \left( \theta \right) = \cot \theta on the interval \left[ -2 \pi, 2 \pi \right].

Worked Solution
Create a strategy

We can complete the table of values by evaluating \cot\theta=\dfrac{\cos \theta}{\sin \theta}, then plot the points \left(\theta,\cot\theta\right) on a coordinate plane.

Apply the idea
\theta0\dfrac{\pi}{4}\dfrac{\pi}{2}\dfrac{3 \pi}{4}\pi\dfrac{5 \pi}{4}\dfrac{3 \pi}{2}\dfrac{7 \pi}{4}2 \pi
\cos \theta1\dfrac{\sqrt{2}}{2}0-\dfrac{\sqrt{2}}{2}-1-\dfrac{\sqrt{2}}{2}0\dfrac{\sqrt{2}}{2}1
\sin \theta0\dfrac{\sqrt{2}}{2}1\dfrac{\sqrt{2}}{2}0-\dfrac{\sqrt{2}}{2}-1-\dfrac{\sqrt{2}}{2}0
\cot \theta\text{undefined}10-1\text{undefined}10-1\text{undefined}

The asymptotes of the cotangent function occur at multiples of \pi, which is where the values of the sine function approach and become equal to 0.

-2\pi
-\frac{3}{2}\pi
-1\pi
-\frac{1}{2}\pi
\frac{1}{2}\pi
1\pi
\frac{3}{2}\pi
2\pi
\theta
-2
-1
1
2
f \left( \theta \right)

To graph the function from -2\pi to 0, we can use the fact that angles that are coterminal on the unit circle will result in the same values of \cot \theta. For example, \theta= \dfrac{-\pi}{2} is coterminal to \alpha= \dfrac{3 \pi}{2}, and since \cot \left( \dfrac{3\pi}{2} \right)=0, \cot \left( \dfrac{-\pi}{2} \right) = 0 also. The following coterminal angles give the exact values:

\cot \left( \dfrac{-3 \pi}{2} \right) = \cot \left( \dfrac{\pi}{2} \right) = 0

\cot \left( \dfrac{-7 \pi}{4} \right) = \cot \left( \dfrac{\pi}{4} \right) = 1

\cot \left( \dfrac{-5 \pi}{4} \right) = \cot \left( \dfrac{3\pi}{4} \right) = -1

\cot \left( \dfrac{-3 \pi}{4} \right) = \cot \left( \dfrac{5\pi}{4} \right) = 1

\cot \left( \dfrac{- \pi}{4} \right) = \cot \left( \dfrac{7\pi}{4} \right) = -1

We can now graph the periodic function:

-2\pi
-\frac{3}{2}\pi
-1\pi
-\frac{1}{2}\pi
\frac{1}{2}\pi
1\pi
\frac{3}{2}\pi
2\pi
\theta
-2
-1
1
2
f \left( \theta \right)
c

Compare the domain and range of f \left( \theta \right) = \cot \theta to g \left( \theta \right) = \tan \theta.

Worked Solution
Create a strategy

For the parent tangent function:

  • Domain: x \neq \dfrac{\pi}{2} + n \pi, n is any integer

  • Range: \left( -\infty, \infty \right)

For the cotangent function:

  • Domain: x \neq n \pi, n is any integer

  • Range: \left( -\infty, \infty \right)

Apply the idea

The range for the tangent and cotangent functions is the same. However, the asymptotes of the functions are different, so the domain for the functions is different.

The excluded values of cotangent are at multiplies of \pi whereas the excluded values for the tangent function are at odd multiples of \dfrac{\pi}{2}.

Reflect and check

Note that the domain for the functions relates to their asymptotes and the unit circle, and recall that since the tangent function is the ratio \dfrac{\sin \theta}{\cos \theta}, anywhere cosine is equal to 0 on the unit circle, tangent must be undefined.

Idea summary

It will be useful to recall the relationship between the graphs of the three basic trigonometric functions and their reciprocal graphs:

Graphs of the basic trigonometric functions. On the top row, graphs of sine theta, cosine theta, and tangent theta are shown. Below the graph of sine theta is the graph of cosecant theta, below cosine theta is secant theta, and below tangent theta is cotangent theta. Speak to your teacher for more details.

Outcomes

F.IF.B.4

For a function that models a relationship between two quantities, interpret key features of graphs and tables in terms of the quantities, and sketch graphs showing key features given a verbal description of the relationship. Key features include: intercepts; intervals where the function is increasing, decreasing, positive, or negative; relative maximums and minimums; symmetries; end behavior; and periodicity.

F.IF.C.7

Graph functions expressed symbolically and show key features of the graph, by hand in simple cases and using technology for more complicated cases.

F.IF.C.7.E

Graph exponential and logarithmic functions, showing intercepts and end behavior, and trigonometric functions, showing period, midline, and amplitude.

F.BF.B.4

Find inverse functions.

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