ORCCA Point-Slope Form

Section 3.6 Point-Slope Form

Objectives: PCC Course Content and Outcome Guide

In Section 5, we learned that a linear equation can be written in slope-intercept form. This section covers an alternative that is often more useful depending on the application: “point-slope form”.

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Figure 3.6.1. Alternative Video Lesson

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Subsection 3.6.1 Point-Slope Motivation and Definition

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Since 1990, the population of the United States has been growing by about

2.865

million people per year. Also, back in 1990, the population was

253

million. Since the rate of growth has been roughly constant, a linear model is appropriate. Let’s write an equation to model this.

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We consider using slope-intercept form, but we would need to know the

y

-intercept, and nothing in the background tells us that. We’d need to know the population of the United States back in the year 0, before there even was a United States.

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We could do some side work to calculate the

y

-intercept, but let’s try something else instead. Here are some things we know:

The slope equation for a line in general is $m = \frac{y_{2} - y_{1}}{x_{2} - x_{1}} .$
The slope of our line is $m = 2.865 \frac{million people}{year},$ or $m = \frac{2.865 million people}{1 year} .$
One point on the line is $(x_{1}, y_{1}) = (1990, 253),$ because in 1990, the population was $253$ million.

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If we use the generic variables

(x, y)

to represent a point somewhere on this line, then the rate of change from

(1990, 253)

(x, y)

must be

2.865 .

\frac{y - 253}{x - 1990} = 2.865 .

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There is good reason to isolate

y

in this equation, so we do that.

\begin{aligned} \frac{y - 253}{x - 1990} & = 2.865 \\ \frac{y - 253}{x - 1990} \cdot (x - 1990) & = 2.865 \cdot (x - 1990) \\ y - 253 & = 2.865 (x - 1990) & (could distribute, but don't) \\ y & = 2.865 (x - 1990) + 253 \end{aligned}

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This is a good place to pause. We have isolated

y,

and three meaningful numbers appear in the equation: the rate of growth, a certain year, and the population in that year. This is a specific example of point-slope form. Before we look deeper at point-slope form, let’s continue reducing the line equation into slope-intercept form by distributing and combining like terms.

\begin{aligned} y & = 2.865 (x - 1990) + 253 \\ y & = 2.865 x - 5701.35 + 253 & (distributed the 2.865) \\ y & = 2.865 x - 5448.35 & combined like terms \end{aligned}

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One concern with slope-intercept form is that it uses the

y

-intercept, which might have no meaning in the context of an application. For example, here we have found that the

y

-intercept is at

(0, - 5448.35),

but what practical use is that? It’s nonsense to say that in the year 0, the population of the United States was

- 5448.35

million. It doesn’t make sense to have a negative population. It doesn’t make sense to talk about the United States population before there even was a United States. And it doesn’t make sense to use this model for years earlier than 1990 because the background information says clearly that the rate of change we have applies to years 1990 and later.

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For all these reasons, we prefer to have the equation back when it was in the form:

y = 2.865 (x - 1990) + 253

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and we purposely do not distribute the slope.

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Definition 3.6.2. Point-Slope Form.

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When

x

and

y

have a linear relationship where

m

is the slope and

(x_{0}, y_{0})

is some specific point that the line passes through, an equation for this relationship is

\begin{matrix} (3.6.1) & y = m (x - x_{0}) + y_{0} \end{matrix}

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and this equation is called the point-slope form of the line. It is called this because two important features are immediately visible from the numbers in the equation: the slope and one point on the line.

Figure 3.6.3.

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There is a subtraction sign and an addition sign in point-slope form, and you may have trouble remembering which is which. But remember that that the line is supposed to pass through

(x_{0}, y_{0}) .

So substituting

x_{0}

in for

x

should leave

y

equal to

y_{0} .

And it does. For example, consider our example equation

y = 2.865 (x - 1990) + 253 .

Here,

x_{0}

1990

and

y_{0}

253 .

And:

\begin{aligned} y & = 2.865 (x - 1990) + 253 & substitute 1990 for x \dots \\ y & = 2.865 (1990 - 1990) + 253 \\ y & = 2.865 (0) + 253 \\ y & = 253 & \dots and y works out to be 253 \end{aligned}

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The subtraction is exactly where it needs to be to wipe out

m (x - x_{0})

and leave you with

y_{0} .

More generally:

\underset{\overset{↓}{y_{0}}}{y} = m (\overset{\overset{x_{0}}{↓}}{x} - x_{0}) + y_{0}

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Remark 3.6.4. Alternative Point-Slope Form.

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It is also common to define point-slope form as

\begin{matrix} (3.6.2) & y - y_{0} = m (x - x_{0}) \end{matrix}

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by subtracting

y_{0}

from each side. If you learn about point-slope form from some other resource, you may come across this. We feel that the

y = m (x - x_{0}) + y_{0}

form will be more helpful with college algebra, statistics, and calculus.

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Checkpoint 3.6.5.

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Consider the line in this graph:

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Identify a point visible on this line that has integer coordinates, and write it as an ordered pair.
What is the slope of the line?
Use point-slope form to write an equation for this line, making use of a point with integer coordinates.

Explanation.

The visible points with integer coordinates are $(2, - 1),$ $(3, 2),$ and $(4, 5) .$
Several slope triangles are visible where the “run” is $1$ and the “rise” is $3 .$ So the slope is $\frac{3}{1} = 3 .$
Using $(3, 2),$ the point-slope equation is $y = 3 (x - 3) + 2 .$ (You could use other points, like $(2, - 1),$ and get a different-looking equation like $y = 3 (x - 2) + (- 1)$ which simplifies to $y = 3 (x - 2) - 1 .$ )

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In Checkpoint 5, the solution explains that each of the following are acceptable equations for the same line:

\begin{aligned} y & = 3 (x - 3) + 2 & y & = 3 (x - 2) - 1 \end{aligned}

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The first uses

(3, 2)

as a point on the line, and the second uses

(2, - 1) .

Are those two equations really equivalent? Let’s distribute and simplify each of them to get slope-intercept form.

\begin{aligned} y & = 3 (x - 3) + 2 & y & = 3 (x - 2) - 1 \\ y & = 3 x - 9 + 2 & y & = 3 x - 6 - 1 \\ y & = 3 x - 7 & y & = 3 x - 7 \end{aligned}

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So, yes. It didn’t matter which point we used to write a point-slope equation. We get different-looking equations that still represent the same line.

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Point-slope form is preferable when we know a line’s slope and a point on it, but we don’t know the

y

-intercept. We recognize that distributing the slope and combining like terms can always be used to find the line’s slope-intercept form.

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Checkpoint 3.6.6.

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Plot the line with equation

y = \frac{2}{5} (x - 1) + 4 .

Explanation.

We can see from the equation that

(1, 4)

is a point on the line. The first step in making a plot is to go to that point on the graph. We also see the slope is

\frac{2}{5},

so from our launch point of

(1, 4),

we can move forward

5

and up

2

to find a second point on the line.

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Example 3.6.7.

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A spa chain has been losing customers at a roughly constant rate since the year 2018. In 2021, it had

2975

customers; in 2024, it had

2585

customers. Management estimated that the company will go out of business once its customer base decreases to

1800 .

If this trend continues, when will the company close?

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The given information tells us two points on the line:

(2021, 2975)

and

(2024, 2585) .

The slope formula will give us the slope. After labeling those two points as

(\overset{x_{1}}{2021}, \overset{y_{1}}{2975})

and

(\overset{x_{2}}{2024}, \overset{y_{2}}{2585}),

we have:

\begin{aligned} slope & = \frac{y_{2} - y_{1}}{x_{2} - x_{1}} \\ = \frac{2585 - 2975}{2024 - 2021} \\ = \frac{- 390}{3} \\ = - 130 \end{aligned}

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And considering units, this means they are losing

130

customers per year.

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We could make an equation for this line using slope-intercept form, but then we would need to calculate the

y

-intercept, which would correspond to the number of customers in year

0 .

We’d be working with numbers that have no real-world meaning.

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For point-slope form, since we calculated the slope, we know at least this much:

y = - 130 (x - x_{0}) + y_{0} .

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Now we can pick one of those two given points, say

(2021, 2975),

and get the equation

y = - 130 (x - 2021) + 2975 .

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Note that all three numbers in this equation have meaning in the context of the spa chain. The

- 130

tells us how many customers are leaving per year, the

2021

represents a year, and the

2975

tells us the number of customers in that year.

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We’re ready to answer the question about when the chain might go out of business. We need to substitute the given value of

1800

into the appropriate place in our equation. In order to substitute correctly, we must clearly understand what the variable

y

represents including its units, and what the variable

x

represents including its units. Write down those definitions first in any question you attempt to answer. It will save you time in the long run, and avoid frustration. Knowing the variable

y

represents the number of customers in a given year allows one to understand that

y

must be replaced with

1800

customers. Knowing the variable

x

represents a year allows one to understand that

x

will not be substituted, because we are trying to solve for what year something happens.

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After substituting

y

in the equation with

1800,

we will solve for

x,

and find the answer we seek.

\begin{aligned} y & = - 130 (x - 2021) + 2975 \\ 1800 & = - 130 (x - 2021) + 2975 \\ 1800 - 2975 & = - 130 (x - 2021) \\ - 1175 & = - 130 (x - 2021) \\ \frac{- 1175}{- 130} & = \frac{- 130 (x - 2021)}{- 130} \\ 9.038 & \approx x - 2021 \\ 9.038 + 2021 & \approx x \\ 2030 & \approx x \end{aligned}

Figure 3.6.8.

y = - 130 (x - 2021) + 2975

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We find that the company is headed toward a collapse in 2030.

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Figure 8 illustrates one line representing the spa’s customer base, and another line representing the customer level that would cause the business to close. To make a graph of

y = - 130 (x - 2021) + 2975,

we first marked the point

(2021, 2975)

and from there used the slope of

- 130 .

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Checkpoint 3.6.9.

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If we go state by state and compare the Republican presidential candidate’s 2012 vote share (

x

) to the Republican presidential candidate’s 2016 vote share (

y

), we get the following graph (called a “scatterplot”, used in statistics) where a trendline has been superimposed.

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Find a point-slope equation for this line. (Note that a slope-intercept equation would use the

y

-intercept coordinate

b,

and that would not be meaningful in context, since no state had anywhere near zero percent Republican vote.)

Explanation.

We need to calculate slope first. And for that, we need to identify two points on the line. conveniently, the line appears to pass right through

(50, 50) .

We have to take a second point somewhere, and

(75, 72)

seems like a reasonable roughly accurate choice. The slope equation gives us that

m = \frac{72 - 50}{75 - 50} = \frac{22}{25} = 0.88 .

Using

(50, 50)

as the point, the point-slope equation would then be

y = 0.88 (x - 50) + 50 .

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Subsection 3.6.2 Using Two Points to Build a Linear Equation

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Since two points can determine a line’s location, we can calculate a line’s equation using just the coordinates from any two points it passes through.

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Example 3.6.10.

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A line passes through

(- 6, 0)

and

(9, - 10) .

Find this line’s equation in both point-slope and slope-intercept form.

Explanation.

We will use the slope formula to find the slope first. After labeling those two points as

(\overset{x_{1}}{- 6}, \overset{y_{1}}{0}) and (\overset{x_{2}}{9}, \overset{y_{2}}{- 10}),

we have:

\begin{aligned} slope & = \frac{y_{2} - y_{1}}{x_{2} - x_{1}} \\ = \frac{-}{-} & (reserving place holders) \\ = \frac{- 0}{- (- 6)} & (fill in first point, vertically) \\ = \frac{- 10 - 0}{9 - (- 6)} & (fill in second point, vertically) \\ = \frac{- 10}{15} \\ = - \frac{2}{3} \end{aligned}

The point-slope equation is

y = - \frac{2}{3} (x - x_{0}) + y_{0} .

Next, we will use

(9, - 10)

and substitute

x_{0}

with

9

and

y_{0}

with

- 10,

and we have:

\begin{aligned} y & = - \frac{2}{3} (x - x_{0}) + y_{0} \\ y & = - \frac{2}{3} (x - 9) + (- 10) \\ y & = - \frac{2}{3} (x - 9) - 10 \end{aligned}

Next, we will change the point-slope equation into slope-intercept form:

\begin{aligned} y & = - \frac{2}{3} (x - 9) - 10 \\ y & = - \frac{2}{3} x + 6 - 10 \\ y & = - \frac{2}{3} x - 4 \end{aligned}

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Checkpoint 3.6.11.

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A line passes through

(37, 40)

and

(- 11, - 60) .

Find equations for this line using both point-slope and slope-intercept form.

Explanation.

First, use the slope formula to find the slope of this line:

\begin{aligned} m = \frac{y_{2} - y_{1}}{x_{2} - x_{1}} & = \frac{- 60 - 40}{- 11 - 37} \\ = \frac{- 100}{- 48} \\ = \frac{25}{12} . \end{aligned}

The generic point-slope equation is

y = m (x - x_{0}) + y_{0} .

We have found the slope,

m,

and we may use

(37, 40)

for

(x_{0}, y_{0}) .

So an equation in point-slope form is

y = \frac{25}{12} (x - 37) + 40 or y = \frac{25}{12} (x + 11) - 60 .

To find a slope-intercept form equation, we can take the generic

y = m x + b

and substitute in the value of

m

we found. Also, we know that

(x, y) = (- 11, - 60)

should make the equation true. So we have

\begin{aligned} y & = m x + b \\ - 60 & = \frac{25}{12} (- 11) + b & (now we may solve for b) \\ - 60 \cdot 12 & = (\frac{25}{12} (- 11) + b) \cdot 12 & (clear the denominator) \\ - 720 & = 25 (- 11) + 12 b & (distribute and multiply) \\ - 720 & = - 275 + 12 b \\ - 720 + 275 & = 264 + 12 b + 275 \\ - 445 & = 12 b \\ \frac{- 445}{12} & = \frac{12 b}{12} & b = - \frac{445}{12} . \end{aligned}

So the slope-intercept equation is

y = \frac{25}{12} - \frac{445}{12} .

Note that the slope-intercept equation has an unfriendly fraction, and the fact that this can happen is another reason to use the point-slope form whenever it is reasonable to do so.

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Subsection 3.6.3 Recognizing Point-Slope Form

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We can tell a lot about a linear equation now that we have learned both slope-intercept form and point-slope form. For example, we can know that

y = 4 x + 2

is in slope-intercept form because it looks like

y = m x + b .

It will graph as a line with slope

4

and vertical intercept

(0, 2) .

Likewise, we know that the equation

y = - 5 (x - 3) + 2

is in point-slope form because it looks like

y = m (x - x_{0}) + y_{0} .

It will graph as a line that has slope

- 5

and will pass through the point

(3, 2) .

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Example 3.6.12.

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For the equations below, state whether they are in slope-intercept form or point-slope form. Then identify the slope of the line and at least one point that the line will pass through.

$y = - 3 x + 2$
$y = 9 (x + 1) - 6$
$y = 5 - x$
$y = - \frac{12}{5} (x - 9) + 1$

Explanation.

The equation $y = - 3 x + 2$ is in slope-intercept form. The slope is $- 3$ and the vertical intercept is $(0, 2) .$
The equation $y = 9 (x + 1) - 6$ is in point-slope form. The slope is $9$ and the line passes through the point $(- 1, - 6) .$
The equation $y = 5 - x$ is almost in slope-intercept form. If we rearrange the right hand side to be $y = - x + 5,$ we can see that the slope is $- 1$ and the vertical intercept is $(0, 5) .$
The equation $y = - \frac{12}{5} (x - 9) + 1$ is in point-slope form. The slope is $- \frac{12}{5}$ and the line passes through the point $(9, 1) .$

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Example 3.6.13.

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Consider the graph in Figure 14.

Using the point-slope form of a line, find three different linear equations for the line shown in the graph. Three integer-valued points are shown for convenience.
Determine the slope-intercept form of the equation of this line.

Figure 3.6.14.

Explanation.

To write any of the equations representing this line in point-slope form, we must first find the slope of the line and we can use the slope formula to do so. We will arbitrarily choose $(0, 30)$ and $(- 5, 42)$ as the two points. Inputting these points into the slope formula yields:

$\begin{aligned} m & = \frac{y_{2} - y_{1}}{x_{2} - x_{1}} \\ = \frac{42 - 30}{- 5 - 0} \\ = \frac{12}{- 5} = - \frac{12}{5} \end{aligned}$

So the slope of the line is $- \frac{12}{5} .$

Next, we need to write an equation in point-slope form based on each point shown. Using the point $(0, 30),$ we have:

$y = - \frac{12}{5} (x - 0) + 30$

(This simplifies to $y = - \frac{12}{5} x + 30 .$ )

The next point is $(20, - 18) .$ Using this point, we can write an equation for this line as:

$y = - \frac{12}{5} (x - 20) - 18$

Finally, we can also use the point $(- 5, 42)$ to write an equation for this line:

$y = - \frac{12}{5} (x - (- 5)) + 42$

which can also be written as:

$y = - \frac{12}{5} (x + 5) + 42$
As $(0, 30)$ is the vertical intercept, we can write the equation of this line in slope-intercept form as $y = - \frac{12}{5} x + 30 .$ It’s important to note that each of the equations that were written in point-slope form simplify to this, making all four equations equivalent.

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Reading Questions 3.6.4 Reading Questions

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1.

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Explain why there are some situations where point-slope form is preferable to slope-intercept form.

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2.

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There are basically two steps to convert a point-slope line equation into a slope-intercept line equation. What are they?

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3.

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If a line has equation

y = 2 (x + 5) + 6,

we can see the line passes through a certain point. To find the

x

-coordinate of that point, you might look at the

5

and know that you should negate that. Instead, you could train yourself to look at the

x

and realize the important number is

- 5

because that is what it takes to .

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A line’s equation is given in point-slope form. Identify the slope and the point on the line that is being singled out.

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1.

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y = 2 (x - 6) + 5

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2.

🔗

y = 3 (x - 2) + 8

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3.

🔗

y = - 4 (x + 8) + 3

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4.

🔗

y = 5 (x + 4) + 7

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5.

🔗

y = 6 (x + 2) - 3

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6.

🔗

y = 6 (x + 7) - 4

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7.

🔗

y = 7 (x - 4) - 9

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8.

🔗

y = 8 (x - 2) - 4

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Construct Point-Slope Form.

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A line passes through the given point with the given slope. Find an equation for the line in point-slope form using the given point.

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9.

🔗

through

(6, 7)

with slope

9

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10.

🔗

through

(5, 3)

with slope

2

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11.

🔗

through

(- 9, - 6)

with slope

3

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12.

🔗

through

(- 7, - 9)

with slope

4

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13.

🔗

through

(5, - 8)

with slope

- 1.7

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14.

🔗

through

(8, - 5)

with slope

0.9

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Point-Slope Given Two Points.

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A line passes through two given points. Find an equation for the line in point-slope form using one of the given points.

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15.

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(7, 3)

and

(4, - 15)

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16.

🔗

(3, 6)

and

(9, 48)

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17.

🔗

(8, - 9)

and

(4, 19)

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18.

🔗

(2, - 3)

and

(- 4, 51)

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19.

🔗

(- 8, - 5)

and

(- 57, 16)

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20.

🔗

(- 6, 7)

and

(29, - 49)

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21.

🔗

(- 4, 1)

and

(6, 15)

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22.

🔗

(- 2, - 7)

and

(- 26, - 10)

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Converting Point-Slope to Slope-Intercept.

🔗

Change the given point-slope equation to slope-intercept form.

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23.

🔗

y = 6 (x - 8) + 5

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24.

🔗

y = 6 (x - 5) + 9

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25.

🔗

y = - 7 (x + 2) + 5

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26.

🔗

y = - 8 (x + 7) + 6

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27.

🔗

y = \frac{2}{7} (x - 9) + 4

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28.

🔗

y = \frac{6}{7} (x - 2) + 3

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29.

🔗

y = - 5.7 (x + 5.3) - 7.6

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30.

🔗

y = - 6.3 (x + 3.6) + 0.1

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Point-Slope Form from a Graph.

🔗

Determine a point-slope form line equation for the given line.

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31.

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32.

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33.

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34.

🔗

35.

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36.

🔗

37.

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38.

🔗

Make Graphs.

🔗

Graph the linear equation by identifying the slope and one point on this line.

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39.

🔗

y = 4 (x - 3) + 2

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40.

🔗

y = 4 (x - 3) + 5

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41.

🔗

y = 2 (x - 3) - 4

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42.

🔗

y = 3 (x - 4) - 2

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43.

🔗

y = \frac{7}{5} (x + 8) - 9

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44.

🔗

y = \frac{2}{9} (x - 7) + 5

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45.

🔗

y = - \frac{2}{5} (x + 3) + 8

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46.

🔗

y = - \frac{2}{5} (x - 7) - 2

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47.

🔗

y = 0.8 (x - 3) + 4

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48.

🔗

y = - 0.4 (x - 2) - 9

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Applications

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49.

🔗

By your cell phone contract, you pay a monthly fee plus

$ 0.04

for each minute you spend on the phone. In one month, you spent

240

minutes over the phone, and had a bill totaling

$ 26.60 .

🔗

Let

x

be the number of minutes you spend on the phone in a month, and let

y

be your total cell phone bill for that month, in dollars. Use a linear equation to model your monthly bill based on the number of minutes you spend on the phone.

A point-slope equation to model this is .
If you spend $200$ minutes on the phone in a month, you would be billed .
If your bill was $$ 34.20$ one month, you must have spent minutes on the phone in that month.

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50.

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A company set aside a certain amount of money in the year 2000. The company spent exactly

$ 35,000

from that fund each year on perks for its employees. In

2004,

there was still

$ 625,000

left in the fund.

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Let

x

be the number of years since 2000, and let

y

be the amount of money, in dollars, left in the fund that year. Use a linear equation to model the amount of money left in the fund after so many years.

A point-slope equation to model this is .
In the year $2011,$ there was left in the fund.
In the year , the fund will be empty.

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51.

🔗

A biologist has been observing a tree’s height. This type of tree typically grows by

0.22

feet each month. Eleven months into the observation, the tree was

13.92

feet tall.

🔗

Let

x

be the number of months passed since the observations started, and let

y

be the tree’s height at that time, in feet. Use a linear equation to model the tree’s height as the number of months pass.

A point-slope equation to model this is .
$30$ months after the observations started, the tree would be feet in height.
months after the observation started, the tree would be $22.94$ feet tall.

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52.

🔗

Scientists are conducting an experiment with a gas in a sealed container. The mass of the gas is measured, and the scientists realize that the gas is leaking over time in a linear way. Each minute, they lose

7.4

grams. Eight minutes since the experiment started, the remaining gas had a mass of

288.6

grams.

🔗

Let

x

be the number of minutes that have passed since the experiment started, and let

y

be the mass of the gas in grams at that moment. Use a linear equation to model the weight of the gas over time.

A point-slope equation to model this is .
$39$ minutes after the experiment started, there would be grams of gas left.
If a linear model continues to be accurate, minutes since the experiment started, all gas in the container will be gone.

🔗

53.

🔗

A company set aside a certain amount of money in the year 2000. The company spent exactly the same amount from that fund each year on perks for its employees. In

2002,

there was still

$ 658,000

left in the fund. In

2007,

there was

$ 433,000

left.

🔗

Let

x

be the number of years since 2000, and let

y

be the amount of money, in dollars, left in the fund that year. Use a linear equation to model the amount of money left in the fund after so many years.

A point-slope equation to model this is .
In the year $2011,$ there was left in the fund.
In the year , the fund will be empty.

🔗

54.

🔗

By your cell phone contract, you pay a monthly fee plus some money for each minute you use the phone during the month. In one month, you spent

250

minutes on the phone, and paid

$ 27.25 .

In another month, you spent

350

minutes on the phone, and paid

$ 33.75 .

🔗

Let

x

be the number of minutes you talk over the phone in a month, and let

y

be your cell phone bill, in dollars, for that month. Use a linear equation to model your monthly bill based on the number of minutes you talk over the phone.

A point-slope equation to model this is .
If you spent $190$ minutes over the phone in a month, you would pay .
If in a month, you paid $$ 41.55$ of cell phone bill, you must have spent minutes on the phone in that month.

🔗

55.

🔗

Scientists are conducting an experiment with a gas in a sealed container. The mass of the gas is measured, and the scientists realize that the gas is leaking over time in a linear way.

🔗

Ten minutes since the experiment started, the gas had a mass of

213

grams.

🔗

Twelve minutes since the experiment started, the gas had a mass of

198.8

grams.

🔗

Let

x

be the number of minutes that have passed since the experiment started, and let

y

be the mass of the gas in grams at that moment. Use a linear equation to model the weight of the gas over time.

A point-slope equation to model this is .
$39$ minutes after the experiment started, there would be grams of gas left.
If a linear model continues to be accurate, minutes since the experiment started, all gas in the container will be gone.

🔗

56.

🔗

A biologist has been observing a tree’s height.

11

months into the observation, the tree was

15.03

feet tall.

20

months into the observation, the tree was

16.2

feet tall.

🔗

Let

x

be the number of months passed since the observations started, and let

y

be the tree’s height at that time, in feet. Use a linear equation to model the tree’s height as the number of months pass.

A point-slope equation to model this is .
$29$ months after the observations started, the tree would be feet in height.
months after the observation started, the tree would be $21.01$ feet tall.

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Section 3.6 Point-Slope Form

Objectives: PCC Course Content and Outcome Guide

Subsection 3.6.1 Point-Slope Motivation and Definition

Definition 3.6.2. Point-Slope Form.

Remark 3.6.4. Alternative Point-Slope Form.

Checkpoint 3.6.5.

Checkpoint 3.6.6.

Example 3.6.7.

Checkpoint 3.6.9.

Subsection 3.6.2 Using Two Points to Build a Linear Equation

Example 3.6.10.

Checkpoint 3.6.11.

Subsection 3.6.3 Recognizing Point-Slope Form

Example 3.6.12.

Example 3.6.13.

Reading Questions 3.6.4 Reading Questions

1.

2.

3.

Exercises 3.6.5 Exercises

Skills Practice

Identify Point and Slope.

1.

2.

3.

4.

5.

6.

7.

8.

Construct Point-Slope Form.

9.

10.

11.

12.

13.

14.

Point-Slope Given Two Points.

15.

16.

17.

18.

19.

20.

21.

22.

Converting Point-Slope to Slope-Intercept.

23.

24.

25.

26.

27.

28.

29.

30.

Point-Slope Form from a Graph.

31.

32.

33.

34.

35.

36.

37.

38.

Make Graphs.

39.

40.

41.

42.

43.

44.

45.

46.

47.

48.

Applications

49.

50.

51.

52.