2.05 Transformations of hyperbolas

Lesson

Worksheet

Practice

Lesson

Transformations - dilation

Use the following applet to explore the effect that $a$a has on the hyperbola $y=\frac{a}{x}$y=ax. Adjust the values of $a$a and try to summarise the effect.

Created with Geogebra

Summary:

$a$a dilates (stretches) the graph by a factor of $a$a from the $x$x-axis
The larger the magnitude of $a$a the further the graph is from the origin
The point $\left(1,1\right)$(1,1) will be stretched to the point $\left(1,a\right)$(1,a)
When $a$a is negative the graph lies in the $2$2nd and $4$4th quadrants. This is a reflection of the graph $y=\frac{\left|a\right|}{x}$y=|a|x in the $x$x-axis.
The graphs still has the same symmetry properties of $y=\frac{1}{x}$y=1x
The graph has a vertical asymptote of $x=0$x=0 and a horizontal asymptote of $y=0$y=0

Can you find the coordinates of the 'corner' point which is the closest point to the origin? Hint: It lies on the line $y=x$y=x.

Transformations - translation

Use the next applet to explore the effect that $h$h and $k$k have on the hyperbola $y=\frac{a}{x-h}+k$y=ax−h+k. Adjust the values of $h$h and $k$k and try to summarise the effect.

Created with Geogebra

Summary:

The hyperbola given by $y=\frac{a}{x-h}+k$y=ax−h+k can be thought of as the basic rectangular hyperbola $y=\frac{a}{x}$y=ax translated horizontally (parallel to the $x$x axis) a distance of $h$h units and translated vertically (parallel to the $y$y axis) a distance of $k$k units
The centre (intersection of the asymptotes) will move to the point $\left(h,k\right)$(h,k)
The orientation of the hyperbola will remain unaltered
Vertical asymptote is translated to $x=h$x=h
Horizontal asymptote in translated to $y=k$y=k

For example, to sketch the hyperbola $y=\frac{12}{x-3}+7$y=12x−3+7, first place the centre at $\left(3,7\right)$(3,7). Then draw in the two orthogonal asymptotes (orthogonal means at right angles) given by $x=3$x=3 and $y=7$y=7. Finally, draw the hyperbola as if it were the basic hyperbola $y=\frac{12}{x}$y=12x but now centred at the point $\left(3,7\right)$(3,7).

The graph of $y=\frac{12}{x-3}+7$y=12x−3+7 as a translation of the graph of $y=\frac{12}{x}$y=12x

Note that the domain includes all values of $x$x not equal to $3$3 and the range includes all values of $y$y not equal to $7$7.

Domain and range

We have seen that the function $y=\frac{a}{x-h}+k$y=ax−h+k has asymptotes given by $x=h$x=h and $y=k$y=k. Thus $x=h$x=h is the only point excluded from the domain and $y=k$y=k is the only point excluded from the range.

We usually state this formally as, in the case of the domain, $x:x\in\mathbb{R},x\ne h$x:x∈ℝ,x≠h and in the case of the range, $y:y\in\mathbb{R},y\ne k$y:y∈ℝ,y≠k. Alternatively, we can use interval notation, then the domain can be written as $\left(-\infty,h\right)\cup\left(h,\infty\right)$(−∞,h)∪(h,∞). And the range can be written as $\left(-\infty,k\right)\cup\left(k,\infty\right)$(−∞,k)∪(k,∞).

Rather than thinking of translations we can also see from the equation that the domain and range exclude these values. From the form $y=\frac{a}{x-h}+k$y=ax−h+k, we can see that $x=h$x=h would cause the denominator to be zero and hence, the expression to be undefined. We can rearrange the equation to either $y=\frac{a}{x-k}+h$y=ax−k+h or $\left(x-h\right)\left(y-k\right)=a$(x−h)(y−k)=a, to see that $y=k$y=k will also cause the equation to be undefined.

Practice questions

QUESTION 1

Consider the graph of $y=\frac{2}{x}$y=2x.

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For positive values of $x$x, as $x$x increases $y$y approaches what value?
$0$0
A
$1$1
B
$-\infty$−∞
C
$\infty$∞
D
As $x$x takes small positive values approaching $0$0, what value does $y$y approach?
$\infty$∞
A
$0$0
B
$-\infty$−∞
C
$\pi$π
D
What are the values that $x$x and $y$y cannot take?

$x$x$=$=$\editable{}$

$y$y$=$=$\editable{}$
The graph is symmetrical across two lines of symmetry. State the equations of these two lines.

$y=\editable{},y=\editable{}$y=,y=

QUESTION 2

This is a graph of $y=\frac{1}{x}$y=1x.

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A cartesian plane is shown with both the x-axis and y-axis ranging from -10 to 10. A hyperbola is plotted with a function $y=\frac{1}{x}$y=1x.

How do we shift the graph of $y=\frac{1}{x}$y=1x to get the graph of $y=\frac{1}{x}+3$y=1x+3?
Move the graph $3$3 units to the left.
A
Move the graph upwards by $3$3 unit(s).
B
Move the graph downwards by $3$3 unit(s).
C
Move the graph $3$3 units to the right.
D
Hence plot $y=\frac{1}{x}+3$y=1x+3 on the same graph as $y=\frac{1}{x}$y=1x.

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A cartesian plane is shown with both the x-axis and y-axis ranging from -10 to 10. A hyperbola is drawn with a function $y = 1/x$ .

QUESTION 3

Consider the function $y=\frac{2}{x-4}+3$y=2x−4+3.

Fill in the gap to state the domain of the function.

domain$=$={$x$x$\in$∈$\mathbb{R}$ℝ; $x\ne\editable{}$x≠}
State the equation of the vertical asymptote.
As $x$x approaches $\infty$∞, what value does $y$y approach?
Hence state the equation of the horizontal asymptote.
State the range of the function.

range$=$={$y$y$\in$∈$\mathbb{R}$ℝ; $y\ne\editable{}$y≠}
Which of the following is the graph of the function?
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A
Loading Graph...
B
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C
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D