3.03 Slope-intercept form

What is the slope of the line shown in the graph?

The slope of a line is equal to the vertical 'rise' divided the by horizontal 'run'. It is the ratio of the vertical change to the horizontal change.

Considering two points from the graph: (0,1) and (5,0), from (0,1) requires moving 1 unit down and 5 units to the right.

The slope is \dfrac{-1}{5} or -\dfrac{1}{5}.

What is the y-value of the y-intercept of the line shown in the graph?

The y-intercept is the point where the line intersects the y-axis.

Looking at the graph, the line intersects the y-axis at point (0,1). Thus, the y-value of the y-intercept is y=1.

Write the equation of the line in slope-intercept form.

Substitute the values of the slope and y-intercept in the slope-intercept form of the equation of a line.

We can check our equation using points from the graph. Since each point must be a solution to our equation, choose any point on the line.

For this example, choose (5, 0).

Since it is true that 0=0, this point satisfies our equation.

Find the domain and range of the line.

The domain of a line in the graph represents all possible x-values that the line covers.

The range of a line in the graph represents all possible y-values that the line covers.

Domain: -\infty < x < \infty

Range: -\infty < y < \infty

We can see from the graph that the line extends without any breaks or endpoints along the x and y-axis, confirming that the domain includes all real numbers.

The domain in interval notation is:

(-\infty,\,\infty)

The domain in set notation is:

\{x\,|\,x \in \Reals\}

The range in interval notation is:

(-\infty,\,\infty)

The range in set notation is:

\{ y\,|\,y \in \Reals \}

A line with a slope of \dfrac{1}{2} and a y-intercept of -3.

Subtitute the values of the slope and y-intercept in the slope-intercept form

A line with a slope of -3 and passes through the point (2,3).

Subtitute the slope and point in the slope-intercept form, and solve for the y-intercept before rewriting.

A line that passes through the points (-4, 5) and (8,8).

Subtitute the given points into the slope formula to find slope. Use the slope and one point to solve for the y-intercept before rewriting in slope-intercept form.

-4y=12-8x

Slope-intercept form is y=mx+b, where m is slope and b is the y-intercept.

Each term will be divided by -4 and simplified.

The slope-intercept form of -4y=12-8x is y=2x-3.

Slope is the simplified ratio of \dfrac{\text{vertical change}}{\text{horizontal change}}. By looking at the graph, we could see a change of \dfrac{-8}{-4} by counting down and left between points. This rate of change matches the simplified ratio of \dfrac{2}{1}, or a slope of 2.

7x-14y=-28

Isolate the y and rearrange terms to write in slope-intercept form, y=mx+b.

The x term will be moved first then divide by the coefficient of y.

The slope-intercept form of 7x-14y=-28 is y=\dfrac{1}{2}x+2.

Other forms of equations will create the same graphs as slope-intercept form, but may highlight different information.

By creating a table of values and graphing, we see that 7x-14y=-28 has the same slope and y-intercept as y=\dfrac{1}{2}x+2.

y+2=-\dfrac{2}{3}(x-6)

Slope-intercept form is y=mx+b. Distribute any values outside parentheses and rearrange terms to isolate y.

We will first distribute the -\dfrac{2}{3} then isolate the y to write the equation in slope-intercept form.

The slope-intercept form of y+2=-\dfrac{2}{3}(x-6) is y=-\dfrac{2}{3}x+2.

Determine the linear equation in slope-intercept form that represents this situation.

We can pick two points to calculate the rate of change for the slope. Then we can recognize that the y-intercept is given in the table of values.

Find the slope using the values \left(0,\,30\right) and \left(1,\,28\right):

Notice that the initial value, or y-intercept is given in the table as \left(0,\,30\right).

Writing in the form y=mx+b the equation that represents this situation is y=-2x+30.

If we had not noticed that the y-intercept was given, we could have substituted in any pair of values for x and y, and solved for b.

Draw the graph of this linear relationship with a clearly labeled scale. Only show the viable solutions.

We can't have a negative time (x \geq 0) and we should end the graph when the tub is empty (y=0). To plan our graph, we need to find when the tub is empty.

To find when the tub is empty:

This tells us that we have the restriction that 0 \leq x\leq 15 and 0 \leq y\leq 30, which will help us choose the appropriate axes and scale.

We know that the bathtub begins with 30 gallons which is represented by the y-intercept at (0,30) and that the slope of the linear equation is -2 which means that the tub loses 2 gallons of water every minute until there is no water in the tub at 15 minutes.

We can also graph the slope by using the idea of \dfrac{\text{rise}}{\text{run}}. Since the slope is -2, we can write it as a fraction \dfrac{-2}{1} and identify that the change in y-values (or rise) is -2 and that the change in x-values (or run) is 1.

Find the domain and range.

The domain of a function represents all possible x-values.

The range of a function represents all possible y-values.

Consider values that may fit the pattern but do not fit the context.

Domain: 0 \leq x \leq 15

Notice that even though negative x-values could fit the pattern, it does not make sense with the context to have a negative amount of time.

Range: 0 \leq y \leq 30

In the context, water is never added so it can never be above the starting amount of 30 gallons. Continuing the pattern, the y-value will never drop below empty, or 0 gallons.

Describe how the graph would change if, instead, there were initially 40 gallons of water in the tub, and it emptied at 2.5 gallons per minute.

The initial value is represented by the y-intercept on the graph. The rate of change is represented by the slope of the graph. We should consider how these are changing from the original question.

The original question had an initial value of 30 gallons, and the new scenario has an initial value of 40 gallons. This means the new y-intercept will be higher on the y-axis.

The original question had a rate of change of -2 as it was decreasing at 2 gallons per minute. The new scenario has a rate of change of -2.5 as it is emptying at 2.5 gallons per minute. This means the slope will be steeper in the new scenario.

We can see this on the graph:

Notice that despite starting with 10 extra gallons of water, the tub with 40 gallons of water only takes 1 more minute to empty than the 30-gallon tub, because it is emptying at a faster rate. This is reflected in the graph as a steeper slope. The second function is decreasing at a greater rate than the first.