Like lines, logarithmic graphs will always have an x-intercept. This is the point on the graph which touches the x-axis. We can find this by setting y=0 and finding the value of x. For example, the x-intercept of y=\log_{2}x is (1,0).
Similarly, we can look for y-intercepts by setting x=0 and then solving for y. Because this is a logarithmic equation, there could be 0 or 1 solutions, and there will be the same number of y-intercepts. For example, the graph of y=\log_{2}x has no y-intercept.
Logarithmic graphs have a vertical asymptote which is the vertical line which the graph approaches but does not touch. For example, the vertical asymptote of y=\log_{2}x is x=0.
Consider the function y = \log_{4} x.
Complete the table of values for y = \log_{4} x, rounding any necessary values to two decimal places.
x | 0.3 | 1 | 2 | 3 | 4 | 5 | 10 | 20 |
---|---|---|---|---|---|---|---|---|
y | -0.87 | 0.79 | 1.66 |
Which of the following is the graph of y = \log_{4} x?
The graph of a logarithmic equation of the form y=a\log_{B}(x-h) + k is a logarithmic graph.
Logarithmic graphs have an x-intercept and can have 0 or 1 y-intercepts, depending on the solutions to the logarithmic equation.
Logarithmic graphs have a vertical asymptote which is the vertical line that the graph approaches but does not intersect.
A logarithmic graph can be vertically translated by increasing or decreasing the y-values by a constant number. So to translate y=\log_{2}x up by k units gives us y=\log_{2}x + k.
Similarly, a logarithmic graphh can be horizontally translated by increasing or decreasing the x-values by a constant number. However, the x-value together with the translation must both be in the logarithm. That is, to translate y=\log_{2}x to the left by h units we get y=\log_{2}(x+h).
A logarithmic graph can be vertically scaled by multiplying every y-value by a constant number. So to expand the logarithmic graph y=\log_{2}x by a scale factor of a we get y=a \log_{2}x. We can compress an exponential graph by dividing by the scale factor instead.
We can vertically reflect a logarithmic graph about the x-axis by taking the negative of the y-values. So to reflect y=\log_{2}x about the x-axis gives us y=-\log_{2}x.
We can similarly horizontally reflect a logarithmic graph about the y-axis by taking the negative of the x-values. So to reflect y=\log_{2}x about the y-axis gives us y=\log_{2}(-x).
Use the following applet to explore transformations of the graph of a logarithmic function by dragging the sliders.
Changing B changes the steepness of the graph. Changing A changes the steepness of the graph and negative values of A flip the curve horizontally. Changing h shifts the curve horizontally, and changing k shifts the curve vertically.
A graph of the function y = \log_{3} x is shown below.
A graph of the function y = \log_{3} x + 3 can be obtained from the original graph by transforming it in some way.
Complete the table of values below for y=\log_{3} x:
x | \dfrac{1}{3} | 1 | 3 | 9 |
---|---|---|---|---|
\log_3 x |
Now complete the table of values below for y=\log_{3} x + 3:
x | \dfrac{1}{3} | 1 | 3 | 9 |
---|---|---|---|---|
\log_3 x +3 |
Which of the following is a graph of y=\log_{3} x +3?
Which features of the graph are unchanged after it has been translated 3 units upwards?
Given the graph of y=\log_{6} (-x) , draw the graph of y=5\log_{6} (-x) on the same plane.
Logarithmic graphs can be transformed in the following ways (starting with the logarithmic graph defined by y=\log_{2} x):
Vertically translated by k units: y=\log_{2} x + k
Horizontally translated by h units: y=\log_{2} (x-h)
Vertically scaled by a scale factor of a: y=a\log_{2} x
Vertically reflected about the x-axis: y=-\log_{2} x
Horizontally reflected about the y-axis: y=\log_{2} (-x)