11.14 Gradient
Increasing and decreasing
Some lines have increasing slopes, like these:
And some have decreasing slopes, like these:
This applet will let you explore lines with positive and negative gradients:
Gradient
The slope of a line is a measure of how steep it is. In mathematics we call this the gradient.
A gradient is a single value that describes:
- if a line is increasing (has positive gradient)
- if a line is decreasing (has negative gradient)
- how far up or down the line moves (how the $y$y-value changes) with every step to the right (for every $1$1 unit increase in the $x$x-value)
Take a look at this line, where the horizontal and vertical steps are highlighted:
We call the horizontal measurement the run and the vertical measurement the rise. For this line, a run of $1$1 means a rise of $2$2, so the line has gradient $2$2.
Sometimes it is difficult to measure how far the line goes up or down (how much the $y$y-value changes) in $1$1 horizontal unit, especially if the line doesn't line up with the grid points on the $xy$xy-plane. In this case we calculate the gradient by using a formula:
$\text{gradient }=\frac{\text{rise }}{\text{run }}$gradient =rise run
The rise and run can be calculated from using any two points on the line.
Finding the gradient from a graph
You can find the rise and run of a line by drawing a right triangle created by any two points on the line. The line itself forms the hypotenuse.
This line has a gradient of $\frac{\text{rise }}{\text{run }}=\frac{4}{3}$rise run =43
In this case, the gradient is positive because, over the $3$3 unit increase in the $x$x-values, the $y$y-value has increased. If the $y$y-value decreased as the $x$x-value increases, the gradient would be negative.
This applet allows you to see the rise and run between two points on a line of your choosing:
Finding the gradient from a pair of coordinates
If you have a pair of coordinates, such as $A$A$\left(3,6\right)$(3,6) and $B$B$\left(7,-2\right)$(7,−2), we can find the gradient of the line between these points using the same formula. It is a good idea to draw a quick sketch of the points, which helps us quickly identify what the line will look like:
Already we can tell that the gradient will be negative, since the line moves downward as we go from left to right.
The rise is the difference in the $y$y-values of the points. We take the $y$y-value of the rightmost point and subtract the $y$y-value of the leftmost point to describe the change in vertical distance from $A$A to $B$B:
$\text{rise}=-2-6=-8$rise=−2−6=−8
The run is the difference in the $x$x-values of the points. We take the $x$x-value of the rightmost point and subtract the $x$x-value of the leftmost point to describe the change in horizontal distance from $A$A to $B$B:
$\text{run}=7-3=4$run=7−3=4
Notice that we subtracted the $x$x-values and the $y$y-values in the same order - we check our sketch, and it does seem sensible that between $A$A and $B$B there is a rise of $-8$−8 and a run of $4$4. We can now put these values into our formula to find the gradient:
| $\text{gradient }$gradient | $=$= | $\frac{\text{rise }}{\text{run }}$rise run |
| $=$= | $\frac{-8}{4}$−84 | |
| $=$= | $-2$−2 |
We have a negative gradient, as we suspected. Now we know that when we travel along this line a step of $1$1 in the $x$x-direction means a step of $2$2 down in the $y$y-direction.
Let's just remind ourselves how we calculated the rise and run again.
rise = $y_2-y_1$y2−y1
run = $x_2-x_1$x2−x1
This means we can generate a new rule for finding the gradient if we are given two points.
For any two points $\left(x_1,y_1\right)$(x1,y1) and $\left(x_2,y_2\right)$(x2,y2)
We can find the gradient using the formula:
$\frac{y_2-y_1}{x_2-x_1}$y2−y1x2−x1
Gradient of horizontal and vertical lines
Horizontal Lines
On horizontal lines, the $y$y-value is always the same for every point on the line. In other words, there is no rise- it's completely flat.
Let's look at the coordinates for $A$A, $B$B and $C$C on this line.
$A$A$\left(-8,4\right)$(−8,4)
$B$B$\left(-2,4\right)$(−2,4)
$C$C$\left(7,4\right)$(7,4)
All the $y$y-coordinates are the same. Every point on the line has a $y$y-value equal to $4$4, regardless of the $x$x-value.
The equation of this line is $y=4$y=4.
Since gradient is calculated by $\frac{\text{rise }}{\text{run }}$rise run and there is no rise (i.e. $\text{rise }=0$rise =0), the gradient of a horizontal line is always $0$0.
Vertical Lines
On vertical lines, the $x$x-value is always the same for every point on the line.
Now, let's look at the coordinates for $A$A, $B$B and $C$C on this line.
$A$A$\left(-3,8\right)$(−3,8)
$B$B$\left(-3,3\right)$(−3,3)
$C$C$\left(-3,-3\right)$(−3,−3)
All the $x$x-coordinates are the same, $x=-3$x=−3, regardless of the $y$y-value.
The equation of this line is $x=-3$x=−3.
Vertical lines have no "run" (i.e. $\text{run }=0$run =0).
If we substituted this into the $\frac{\text{rise }}{\text{run }}$rise run equation, we'd have a $0$0 as the denominator of the fraction. However, fractions with a denominator of $0$0 are undefined.
So, the gradient of vertical lines is always undefined.
Question 1
Consider the interval between $A$A$\left(-3,4\right)$(−3,4) and $B$B$\left(3,16\right)$(3,16).
Find the rise (change in the $y$y value) between point $A$A and $B$B.
Find the run (change in the $x$x value) between point $A$A and $B$B.
Find the gradient of the interval $AB$AB.
Question 2
What is the gradient of any line parallel to the $x$x-axis?
Question 3
What is the gradient of the line going through $A$A and $B$B?
Question 4
Consider the line $y=-2x+8$y=−2x+8.
Find the $y$y-intercept.
Enter each line of work as an equation.
Find the $x$x-intercept.
Enter each line of work as an equation.
Draw a graph of the line.
Loading Graph...Find the gradient of the line by substituting the intercepts into the gradient formula.