3.09 Graphs of logarithmic functions
Graphs of logarithmic functions
The graph of a logarithmic function $y=\log_ax$y=logax is unsurprisingly related to the graph of the exponential function $y=a^x$y=ax. In particular, they are a reflection of each other across the line $y=x$y=x. This is because exponential and logarithmic functions are inverse functions.
Graphs of $a^x$ax and $\log_ax$logax, for $a>1$a>1
As these functions are a reflection of each other, we can observe the following properties of the graphs of logarithmic functions of the form $y=\log_bx$y=logbx:
- Domain: the argument, $x$x, is restricted to only positive values. That is, $x>0$x>0.
- Range: all real $y$y values can be obtained by a logarithm
- Asymptotes: there is a vertical asymptote at $x=0$x=0 (on the $y$y-axis) for all logarithmic functions. As a result, there is no $y$y-intercept.
- $x$x-intercept: The logarithm of $1$1 is $0$0, regardless of the base used. As a result, the graph of a logarithmic function intersects the $x$x-axis at $\left(1,0\right)$(1,0).
If the base $b$b is greater than $1$1 then the function increases across the entire domain $x>0$x>0. For $0
The following graph shows $y=\log_2\left(x\right)$y=log2(x) and $y=\log_{0.5}\left(x\right)$y=log0.5(x) illustrating the distinctive shape of the log curve.
Two particular log curves from the family of log functions with $b>1$b>1 are shown below. The red curve is the curve of the function $f(x)=\log_2\left(x\right)$f(x)=log2(x), and the blue curve is the curve of the function $g(x)=\log_4\left(x\right)$g(x)=log4(x).
The points shown on each curve shown help to demonstrate the way the gradient of the curve changes as $b$b increases in value.
The following log graph applet allows you to experiment with different bases. You should note that as the base increases beyond $1$1 the rate of increase in the size of the logarithm decreases.
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As you move the base back again closer and closer to $1$1 from above, the rate increases so that the curve becomes more and more vertical. You should be able to see why the function cannot exist for bases equal to $1$1.
For positive bases less than $1$1, try moving the slider across the full range of values. What do you notice?
Practice question
Question 1
Consider the function $y=\log_4x$y=log4x, the graph of which has been sketched below.
Complete the following table of values.
$x$x $\frac{1}{16}$116 $\frac{1}{4}$14 $4$4 $16$16 $256$256 $y$y $\editable{}$ $\editable{}$ $\editable{}$ $\editable{}$ $\editable{}$ Determine the $x$x-value of the $x$x-intercept of $y=\log_4x$y=log4x.
How many $y$y-intercepts does $\log_4x$log4x have?
Determine the $x$x value for which $\log_4x=1$log4x=1.
Transformations of the logarithmic graph $y=\log_ax+c$y=logax+c
Vertical translation
Recall that adding a constant to a function corresponds to translating the graph vertically. So the graph of $g\left(x\right)=\log_ax+c$g(x)=logax+c is a vertical translation of the graph of $f\left(x\right)=\log_ax$f(x)=logax. The translation is upwards if $c$c is positive, and downwards if $c$c is negative.
Graphs of $f\left(x\right)=\log_ax$f(x)=logax and $g\left(x\right)=\log_ax+c$g(x)=logax+c, for $c<0$c<0.
Notice that the asymptote is not changed by a vertical translation, and is still the line $x=0$x=0. The $x$x-intercept has changed however, and now occurs at a point further along the $x$x-axis. The original $x$x-intercept (which was at $\left(1,0\right)$(1,0)) has now been translated vertically to $\left(1,k\right)$(1,k) and is no longer on the $x$x-axis.
Worked example
example 1
The graphs of the function $f\left(x\right)=\log_3\left(-x\right)$f(x)=log3(−x) and another function $g\left(x\right)$g(x) are shown below.
(a) Describe the transformation used to get from $f\left(x\right)$f(x) to $g\left(x\right)$g(x).
Think: $g\left(x\right)$g(x) has the same general shape as $f\left(x\right)$f(x), just translated upwards. We can figure out how far it has been translated by looking at the distance between corresponding points.
Do: The point on $g\left(x\right)$g(x) that is directly above the $x$x-intercepts of $f\left(x\right)$f(x) is at $\left(-1,5\right)$(−1,5), which is $5$5 units higher. In fact, we can see the constant distance of $5$5 units all the way along the function:
So $f\left(x\right)$f(x) has been translated $5$5 units upwards to give $g\left(x\right)$g(x).
(b) Determine the equation of the function $g\left(x\right)$g(x).
Think: We know that $f\left(x\right)$f(x) has been vertically translated $5$5 units upwards to give $g\left(x\right)$g(x). That is, the function has been increased by $5$5.
Do: This means that $g\left(x\right)=\log_3\left(-x\right)+5$g(x)=log3(−x)+5. This function has an asymptote at $x=0$x=0, and the negative coefficient of $x$x means that it takes values to the left of the asymptote, just like $f\left(x\right)$f(x).
A function of the form $y=\log_ax+c$y=logax+c represents a vertical translation by $c$c units of the function $y=\log_ax$y=logax.
- The translation is upwards if $c$c is positive, and downwards if $c$c is negative.
- The asymptote of the translated function remains at $x=0$x=0.