The standard form of the equation of a line is \(ax+by=c\) where \(a\text\) \(b\text\) and \(c\) represent real numbers. While either \(a\) or \(b\) can be zero, they cannot both be zero in the same equation of a line.
To determine points on the line, we replace one of the variables in the equation with a number and solve the resultant equation for the other variable. For example, consider the line with equation \(3x-4y=24\text<.>\) If we wanted to determine the point on the line that has an \(x\)-coordinate of \(4\) we would go through the following process.
\begin 3(4)-4y\amp=24\\ 12-4y\amp=24\\ 12-4y\subtractright\amp=24\subtractright\\ -4y\amp=12\\ \divideunder\amp=\divideunder\\ y\amp=-3 \end
We now know that the point is \((4,-3)\text<.>\)
Similarly, if we wanted to know the point on the line that has a \(y\)-coordinate of \(15\text\) we would do the following.
\begin 3x-4(15)\amp=24\\ 3x-60\amp=24\\ 3x-60\addright\amp=24\addright\\ 3x\amp=84\\ \divideunder\amp=\divideunder\\ x\amp=28 \end
We can conclude that the point is \((28,15)\text<.>\)
The point on a line with an \(x\)-coordinate of zero (if such a point exists) is called the \(y\)-intercept of the line. Similarly, the point with a \(y\)-coordinate of zero is called the \(x\)-intercept of the line.
For example, the \(y\)-intercept of the line shown in Figure 7.2.1 is \((0,-5)\text\) note that this is the point where the line intersects the \(y\)-axis. The \(x\)-intercept of the same line is \((-2,0)\text\) the point where the line intersects the \(x\)-axis.
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Determine the \(x\)-intercept of the line with equation \(-11x+5y=-110\text<.>\)
Since the \(x\)-intercept is a point on the \(x\)-axis, it must have a \(y\)-coordinate of zero. Replacing \(y\) with zero and solving for \(x\) results in \(x=10\text<.>\) So the \(x\)-intercept of the line is the point \((10,0)\text<.>\)
Determine the \(y\)-intercept of the line with equation \(-11x+5y=-110\text<.>\)
Since the \(y\)-intercept is a point on the \(y\)-axis, it must have an \(x\)-coordinate of zero. Replacing \(x\) with zero and solving for \(y\) results in \(y=-21\text<.>\) So the \(y\)-intercept of the line is the point \((0,-21)\text<.>\)
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Similarly, the movement from the \(x\)-intercept to the \(y\)-intercept can be described as "down \(2\text\) left \(3\text\)" and continuing that pattern takes us to the point \((-3,-4)\) which is also a point on the line.
Every line has its on step-like pattern that can be executed either left-to-right or right-to-left. This phenomenon is the basis for the concept of "slope of a line" and is explored in-depth in the next section.
Figure 7.2.7. Drag the points so that the line matches the given equation. A message appears when you are correct.
Determine the indicated ordered pairs (points) on the lines with the given equations.
Complete the entries in Figure 7.2.8 for the line with equation \(3x-y=6\text<.>\) Also, state the \(x\) and \(y\) intercepts of the line.
| \(x\) | \(y\) |
| \(-1\) | |
| \(2\) | |
| \(5\) | |
| \(8\) | |
| \(11\) |
The \(x\)-intercept is \((2,0)\) and the \(y\)-intercept is \((0,-6)\text<.>\)
| \(x\) | \(y\) |
| \(-1\) | \(-9\) |
| \(2\) | \(0\) |
| \(5\) | \(9\) |
| \(8\) | \(18\) |
| \(11\) | \(27\) |