In this section you will:
Just as with the growth of a bamboo plant, there are many situations that involve constant change over time. Consider, for example, the first commercial maglev train in the world, the Shanghai MagLev Train ([link]). It carries passengers comfortably for a 30-kilometer trip from the airport to the subway station in only eight minutes1.
Suppose a maglev train travels a long distance, and maintains a constant speed of 83 meters per second for a period of time once it is 250 meters from the station. How can we analyze the train’s distance from the station as a function of time? In this section, we will investigate a kind of function that is useful for this purpose, and use it to investigate real-world situations such as the train’s distance from the station at a given point in time.
The function describing the train’s motion is a linear function, which is defined as a function with a constant rate of change. This is a polynomial of degree 1. There are several ways to represent a linear function, including word form, function notation, tabular form, and graphical form. We will describe the train’s motion as a function using each method.
Let’s begin by describing the linear function in words. For the train problem we just considered, the following word sentence may be used to describe the function relationship.
The speed is the rate of change. Recall that a rate of change is a measure of how quickly the dependent variable changes with respect to the independent variable. The rate of change for this example is constant, which means that it is the same for each input value. As the time (input) increases by 1 second, the corresponding distance (output) increases by 83 meters. The train began moving at this constant speed at a distance of 250 meters from the station.
Another approach to representing linear functions is by using function notation. One example of function notation is an equation written in the slope-intercept form of a line, where
is the input value,
is the rate of change, and
is the initial value of the dependent variable.
In the example of the train, we might use the notation
where the total distance
is a function of the time
The rate,
is 83 meters per second. The initial value of the dependent variable
is the original distance from the station, 250 meters. We can write a generalized equation to represent the motion of the train.
A third method of representing a linear function is through the use of a table. The relationship between the distance from the station and the time is represented in [link]. From the table, we can see that the distance changes by 83 meters for every 1 second increase in time.
Can the input in the previous example be any real number?
No. The input represents time so while nonnegative rational and irrational numbers are possible, negative real numbers are not possible for this example. The input consists of non-negative real numbers.
Another way to represent linear functions is visually, using a graph. We can use the function relationship from above,
to draw a graph as represented in [link]. Notice the graph is a line. When we plot a linear function, the graph is always a line.
The rate of change, which is constant, determines the slant, or slope of the line. The point at which the input value is zero is the vertical intercept, or y-intercept, of the line. We can see from the graph that the y-intercept in the train example we just saw is
and represents the distance of the train from the station when it began moving at a constant speed.
Notice that the graph of the train example is restricted, but this is not always the case. Consider the graph of the line
Ask yourself what numbers can be input to the function. In other words, what is the domain of the function? The domain is comprised of all real numbers because any number may be doubled, and then have one added to the product.
A linear function is a function whose graph is a line. Linear functions can be written in the slope-intercept form of a line
where
is the initial or starting value of the function (when input,
), and
is the constant rate of change, or slope of the function. The y-intercept is at
The pressure,
in pounds per square inch (PSI) on the diver in [link] depends upon her depth below the water surface,
in feet. This relationship may be modeled by the equation,
Restate this function in words.
To restate the function in words, we need to describe each part of the equation. The pressure as a function of depth equals four hundred thirty-four thousandths times depth plus fourteen and six hundred ninety-six thousandths.
The initial value, 14.696, is the pressure in PSI on the diver at a depth of 0 feet, which is the surface of the water. The rate of change, or slope, is 0.434 PSI per foot. This tells us that the pressure on the diver increases 0.434 PSI for each foot her depth increases.
The linear functions we used in the two previous examples increased over time, but not every linear function does. A linear function may be increasing, decreasing, or constant. For an increasing function, as with the train example, the output values increase as the input values increase. The graph of an increasing function has a positive slope. A line with a positive slope slants upward from left to right as in [link](a). For a decreasing function, the slope is negative. The output values decrease as the input values increase. A line with a negative slope slants downward from left to right as in [link](b). If the function is constant, the output values are the same for all input values so the slope is zero. A line with a slope of zero is horizontal as in [link](c).
The slope determines if the function is an increasing linear function, a decreasing linear function, or a constant function.
is an increasing function if
is a decreasing function if
is a constant function if
Some recent studies suggest that a teenager sends an average of 60 texts per day2. For each of the following scenarios, find the linear function that describes the relationship between the input value and the output value. Then, determine whether the graph of the function is increasing, decreasing, or constant.
Analyze each function.
where
is the number of days. The slope, 60, is positive so the function is increasing. This makes sense because the total number of texts increases with each day.
where
is the number of days. In this case, the slope is negative so the function is decreasing. This makes sense because the number of texts remaining decreases each day and this function represents the number of texts remaining in the data plan after
days.
because the number of days does not affect the total cost. The slope is 0 so the function is constant.
In the examples we have seen so far, the slope was provided to us. However, we often need to calculate the slope given input and output values. Recall that given two values for the input,
and
and two corresponding values for the output,
and
—which can be represented by a set of points,
and
—we can calculate the slope
Note that in function notation we can obtain two corresponding values for the output
and
for the function
and
so we could equivalently write
[link] indicates how the slope of the line between the points,
and
is calculated. Recall that the slope measures steepness, or slant. The greater the absolute value of the slope, the steeper the slant is.
Are the units for slope always
Yes. Think of the units as the change of output value for each unit of change in input value. An example of slope could be miles per hour or dollars per day. Notice the units appear as a ratio of units for the output per units for the input.
The slope, or rate of change, of a function
can be calculated according to the following:
where
and
are input values,
and
are output values.
Given two points from a linear function, calculate and interpret the slope.
If
is a linear function, and
and
are points on the line, find the slope. Is this function increasing or decreasing?
The coordinate pairs are
and
To find the rate of change, we divide the change in output by the change in input.
We could also write the slope as
The function is increasing because
As noted earlier, the order in which we write the points does not matter when we compute the slope of the line as long as the first output value, or y-coordinate, used corresponds with the first input value, or x-coordinate, used. Note that if we had reversed them, we would have obtained the same slope.
If
is a linear function, and
and
are points on the line, find the slope. Is this function increasing or decreasing?
decreasing because
The population of a city increased from 23,400 to 27,800 between 2008 and 2012. Find the change of population per year if we assume the change was constant from 2008 to 2012.
The rate of change relates the change in population to the change in time. The population increased by
people over the four-year time interval. To find the rate of change, divide the change in the number of people by the number of years.
So the population increased by 1,100 people per year.
Because we are told that the population increased, we would expect the slope to be positive. This positive slope we calculated is therefore reasonable.
The population of a small town increased from 1,442 to 1,868 between 2009 and 2012. Find the change of population per year if we assume the change was constant from 2009 to 2012.
Recall from Equations and Inequalities that we wrote equations in both the slope-intercept form and the point-slope form. Now we can choose which method to use to write equations for linear functions based on the information we are given. That information may be provided in the form of a graph, a point and a slope, two points, and so on. Look at the graph of the function
in [link].
We are not given the slope of the line, but we can choose any two points on the line to find the slope. Let’s choose
and
Now we can substitute the slope and the coordinates of one of the points into the point-slope form.
If we want to rewrite the equation in the slope-intercept form, we would find
If we want to find the slope-intercept form without first writing the point-slope form, we could have recognized that the line crosses the y-axis when the output value is 7. Therefore,
We now have the initial value
and the slope
so we can substitute
and
into the slope-intercept form of a line.
So the function is
and the linear equation would be
Given the graph of a linear function, write an equation to represent the function.
Write an equation for a linear function given a graph of
shown in [link].
Identify two points on the line, such as
and
Use the points to calculate the slope.
Substitute the slope and the coordinates of one of the points into the point-slope form.
We can use algebra to rewrite the equation in the slope-intercept form.
This makes sense because we can see from [link] that the line crosses the y-axis at the point
which is the y-intercept, so
Suppose Ben starts a company in which he incurs a fixed cost of $1,250 per month for the overhead, which includes his office rent. His production costs are $37.50 per item. Write a linear function
where
is the cost for
items produced in a given month.
The fixed cost is present every month, $1,250. The costs that can vary include the cost to produce each item, which is $37.50. The variable cost, called the marginal cost, is represented by
The cost Ben incurs is the sum of these two costs, represented by
If Ben produces 100 items in a month, his monthly cost is found by substituting 100 for
So his monthly cost would be $5,000.
If
is a linear function, with
and
find an equation for the function in slope-intercept form.
We can write the given points using coordinates.
We can then use the points to calculate the slope.
Substitute the slope and the coordinates of one of the points into the point-slope form.
We can use algebra to rewrite the equation in the slope-intercept form.
If
is a linear function, with
and
write an equation for the function in slope-intercept form.
In the real world, problems are not always explicitly stated in terms of a function or represented with a graph. Fortunately, we can analyze the problem by first representing it as a linear function and then interpreting the components of the function. As long as we know, or can figure out, the initial value and the rate of change of a linear function, we can solve many different kinds of real-world problems.
Given a linear function
</math>and the initial value and rate of change, evaluate
</math> </strong>
Marcus currently has 200 songs in his music collection. Every month, he adds 15 new songs. Write a formula for the number of songs,
in his collection as a function of time,
the number of months. How many songs will he own at the end of one year?
The initial value for this function is 200 because he currently owns 200 songs, so
which means that
The number of songs increases by 15 songs per month, so the rate of change is 15 songs per month. Therefore we know that
We can substitute the initial value and the rate of change into the slope-intercept form of a line.
We can write the formula
With this formula, we can then predict how many songs Marcus will have at the end of one year (12 months). In other words, we can evaluate the function at
Marcus will have 380 songs in 12 months.
Notice that N is an increasing linear function. As the input (the number of months) increases, the output (number of songs) increases as well.
Working as an insurance salesperson, Ilya earns a base salary plus a commission on each new policy. Therefore, Ilya’s weekly income
depends on the number of new policies,
he sells during the week. Last week he sold 3 new policies, and earned $760 for the week. The week before, he sold 5 new policies and earned $920. Find an equation for
and interpret the meaning of the components of the equation.
The given information gives us two input-output pairs:
and
We start by finding the rate of change.
Keeping track of units can help us interpret this quantity. Income increased by $160 when the number of policies increased by 2, so the rate of change is $80 per policy. Therefore, Ilya earns a commission of $80 for each policy sold during the week.
We can then solve for the initial value.
The value of
is the starting value for the function and represents Ilya’s income when
or when no new policies are sold. We can interpret this as Ilya’s base salary for the week, which does not depend upon the number of policies sold.
We can now write the final equation.
Our final interpretation is that Ilya’s base salary is $520 per week and he earns an additional $80 commission for each policy sold.
[link] relates the number of rats in a population to time, in weeks. Use the table to write a linear equation.
number of weeks, w | 0 | 2 | 4 | 6 |
number of rats, P(w) | 1000 | 1080 | 1160 | 1240 |
We can see from the table that the initial value for the number of rats is 1000, so
Rather than solving for
we can tell from looking at the table that the population increases by 80 for every 2 weeks that pass. This means that the rate of change is 80 rats per 2 weeks, which can be simplified to 40 rats per week.
If we did not notice the rate of change from the table we could still solve for the slope using any two points from the table. For example, using
and
Is the initial value always provided in a table of values like [link]?
No. Sometimes the initial value is provided in a table of values, but sometimes it is not. If you see an input of 0, then the initial value would be the corresponding output. If the initial value is not provided because there is no value of input on the table equal to 0, find the slope, substitute one coordinate pair and the slope into
</math>and solve for
</math> </em>
A new plant food was introduced to a young tree to test its effect on the height of the tree. [link] shows the height of the tree, in feet,
months since the measurements began. Write a linear function,
where
is the number of months since the start of the experiment.
x | 0 | 2 | 4 | 8 | 12 |
H(x) | 12.5 | 13.5 | 14.5 | 16.5 | 18.5 |
Now that we’ve seen and interpreted graphs of linear functions, let’s take a look at how to create the graphs. There are three basic methods of graphing linear functions. The first is by plotting points and then drawing a line through the points. The second is by using the y-intercept and slope. And the third method is by using transformations of the identity function
To find points of a function, we can choose input values, evaluate the function at these input values, and calculate output values. The input values and corresponding output values form coordinate pairs. We then plot the coordinate pairs on a grid. In general, we should evaluate the function at a minimum of two inputs in order to find at least two points on the graph. For example, given the function,
we might use the input values 1 and 2. Evaluating the function for an input value of 1 yields an output value of 2, which is represented by the point
Evaluating the function for an input value of 2 yields an output value of 4, which is represented by the point
Choosing three points is often advisable because if all three points do not fall on the same line, we know we made an error.
Given a linear function, graph by plotting points.
Graph
by plotting points.
Begin by choosing input values. This function includes a fraction with a denominator of 3, so let’s choose multiples of 3 as input values. We will choose 0, 3, and 6.
Evaluate the function at each input value, and use the output value to identify coordinate pairs.
Plot the coordinate pairs and draw a line through the points. [link] represents the graph of the function
The graph of the function is a line as expected for a linear function. In addition, the graph has a downward slant, which indicates a negative slope. This is also expected from the negative, constant rate of change in the equation for the function.
Graph
by plotting points.
Another way to graph linear functions is by using specific characteristics of the function rather than plotting points. The first characteristic is its y-intercept, which is the point at which the input value is zero. To find the y-intercept, we can set
in the equation.
The other characteristic of the linear function is its slope.
Let’s consider the following function.
The slope is
Because the slope is positive, we know the graph will slant upward from left to right. The y-intercept is the point on the graph when
The graph crosses the y-axis at
Now we know the slope and the y-intercept. We can begin graphing by plotting the point
We know that the slope is the change in the y-coordinate over the change in the x-coordinate. This is commonly referred to as rise over run,
From our example, we have
which means that the rise is 1 and the run is 2. So starting from our y-intercept
we can rise 1 and then run 2, or run 2 and then rise 1. We repeat until we have a few points, and then we draw a line through the points as shown in [link].
In the equation
is the y-intercept of the graph and indicates the point
at which the graph crosses the y-axis.
is the slope of the line and indicates the vertical displacement (rise) and horizontal displacement (run) between each successive pair of points. Recall the formula for the slope:
Do all linear functions have y-intercepts?
Yes. All linear functions cross the y-axis and therefore have y-intercepts. (Note: A vertical line is parallel to the y-axis does not have a y-intercept, but it is not a function.)
Given the equation for a linear function, graph the function using the y-intercept and slope.
to determine at least two more points on the line.
Graph
using the y-intercept and slope.
Evaluate the function at
to find the y-intercept. The output value when
is 5, so the graph will cross the y-axis at
According to the equation for the function, the slope of the line is
This tells us that for each vertical decrease in the “rise” of
units, the “run” increases by 3 units in the horizontal direction. We can now graph the function by first plotting the y-intercept on the graph in [link]. From the initial value
we move down 2 units and to the right 3 units. We can extend the line to the left and right by repeating, and then drawing a line through the points.
The graph slants downward from left to right, which means it has a negative slope as expected.
Find a point on the graph we drew in [link] that has a negative x-value.
Possible answers include
or
Another option for graphing is to use a transformation of the identity function
A function may be transformed by a shift up, down, left, or right. A function may also be transformed using a reflection, stretch, or compression.
In the equation
the
is acting as the vertical stretch or compression of the identity function. When
is negative, there is also a vertical reflection of the graph. Notice in [link] that multiplying the equation of
by
stretches the graph of
by a factor of
units if
and compresses the graph of
by a factor of
units if
This means the larger the absolute value of
the steeper the slope.
In
the
acts as the vertical shift, moving the graph up and down without affecting the slope of the line. Notice in [link] that adding a value of
to the equation of
shifts the graph of
a total of
units up if
is positive and
units down if
is negative.
Using vertical stretches or compressions along with vertical shifts is another way to look at identifying different types of linear functions. Although this may not be the easiest way to graph this type of function, it is still important to practice each method.
Given the equation of a linear function, use transformations to graph the linear function in the form
</math></strong>
units.
Graph
using transformations.
The equation for the function shows that
so the identity function is vertically compressed by
The equation for the function also shows that
so the identity function is vertically shifted down 3 units. First, graph the identity function, and show the vertical compression as in [link].
Then show the vertical shift as in [link].
Graph
using transformations.
In [link], could we have sketched the graph by reversing the order of the transformations?
No. The order of the transformations follows the order of operations. When the function is evaluated at a given input, the corresponding output is calculated by following the order of operations. This is why we performed the compression first. For example, following the order: Let the input be 2.
Earlier, we wrote the equation for a linear function from a graph. Now we can extend what we know about graphing linear functions to analyze graphs a little more closely. Begin by taking a look at [link]. We can see right away that the graph crosses the y-axis at the point
so this is the y-intercept.
Then we can calculate the slope by finding the rise and run. We can choose any two points, but let’s look at the point
To get from this point to the y-intercept, we must move up 4 units (rise) and to the right 2 units (run). So the slope must be
Substituting the slope and y-intercept into the slope-intercept form of a line gives
Given a graph of linear function, find the equation to describe the function.
Match each equation of the linear functions with one of the lines in [link].
Analyze the information for each function.
has the same slope, but a different y-intercept. Lines I and III have the same slant because they have the same slope. Line III does not pass through
so
must be represented by line I.
It must pass through the point
and slant upward from left to right. It must be represented by line III.
and a y-intercept of 3. It must pass through the point (0, 3) and slant upward from left to right. Lines I and II pass through
but the slope of
is less than the slope of
so the line for
must be flatter. This function is represented by Line II.
Now we can re-label the lines as in [link].
So far we have been finding the y-intercepts of a function: the point at which the graph of the function crosses the y-axis. Recall that a function may also have an x-intercept, which is the x-coordinate of the point where the graph of the function crosses the x-axis. In other words, it is the input value when the output value is zero.
To find the x-intercept, set a function
equal to zero and solve for the value of
For example, consider the function shown.
Set the function equal to 0 and solve for
The graph of the function crosses the x-axis at the point
Do all linear functions have x-intercepts?
*No. However, linear functions of the form
where
is a nonzero real number are the only examples of linear functions with no x-intercept. For example,
is a horizontal line 5 units above the x-axis. This function has no x-intercepts, as shown in [link].*
The x-intercept of the function is value of
when
It can be solved by the equation
Find the x-intercept of
Set the function equal to zero to solve for
The graph crosses the x-axis at the point
A graph of the function is shown in [link]. We can see that the x-intercept is
as we expected.
Find the x-intercept of
There are two special cases of lines on a graph—horizontal and vertical lines. A horizontal line indicates a constant output, or y-value. In [link], we see that the output has a value of 2 for every input value. The change in outputs between any two points, therefore, is 0. In the slope formula, the numerator is 0, so the slope is 0. If we use
in the equation
the equation simplifies to
In other words, the value of the function is a constant. This graph represents the function
A vertical line indicates a constant input, or x-value. We can see that the input value for every point on the line is 2, but the output value varies. Because this input value is mapped to more than one output value, a vertical line does not represent a function. Notice that between any two points, the change in the input values is zero. In the slope formula, the denominator will be zero, so the slope of a vertical line is undefined.
A vertical line, such as the one in [link], has an x-intercept, but no y-intercept unless it’s the line
This graph represents the line
Lines can be horizontal or vertical.
A horizontal line is a line defined by an equation in the form
A vertical line is a line defined by an equation in the form
Write the equation of the line graphed in [link].
For any x-value, the y-value is
so the equation is
Write the equation of the line graphed in [link].
The constant x-value is
so the equation is
The two lines in [link] are parallel lines: they will never intersect. They have exactly the same steepness, which means their slopes are identical. The only difference between the two lines is the y-intercept. If we shifted one line vertically toward the other, they would become coincident.
We can determine from their equations whether two lines are parallel by comparing their slopes. If the slopes are the same and the y-intercepts are different, the lines are parallel. If the slopes are different, the lines are not parallel.
Unlike parallel lines, perpendicular lines do intersect. Their intersection forms a right, or 90-degree, angle. The two lines in [link] are perpendicular.
Perpendicular lines do not have the same slope. The slopes of perpendicular lines are different from one another in a specific way. The slope of one line is the negative reciprocal of the slope of the other line. The product of a number and its reciprocal is
So, if
are negative reciprocals of one another, they can be multiplied together to yield
To find the reciprocal of a number, divide 1 by the number. So the reciprocal of 8 is
and the reciprocal of
is 8. To find the negative reciprocal, first find the reciprocal and then change the sign.
As with parallel lines, we can determine whether two lines are perpendicular by comparing their slopes, assuming that the lines are neither horizontal nor vertical. The slope of each line below is the negative reciprocal of the other so the lines are perpendicular.
The product of the slopes is –1.
Two lines are parallel lines if they do not intersect. The slopes of the lines are the same.
If and only if
and
we say the lines coincide. Coincident lines are the same line.
Two lines are perpendicular lines if they intersect to form a right angle.
Given the functions below, identify the functions whose graphs are a pair of parallel lines and a pair of perpendicular lines.
Parallel lines have the same slope. Because the functions
and
each have a slope of 2, they represent parallel lines. Perpendicular lines have negative reciprocal slopes. Because −2 and
are negative reciprocals, the functions
and
represent perpendicular lines.
A graph of the lines is shown in [link].
The graph shows that the lines
and
are parallel, and the lines
and
are perpendicular.
If we know the equation of a line, we can use what we know about slope to write the equation of a line that is either parallel or perpendicular to the given line.
Suppose for example, we are given the equation shown.
We know that the slope of the line formed by the function is 3. We also know that the y-intercept is
Any other line with a slope of 3 will be parallel to
So the lines formed by all of the following functions will be parallel to
Suppose then we want to write the equation of a line that is parallel to
and passes through the point
This type of problem is often described as a point-slope problem because we have a point and a slope. In our example, we know that the slope is 3. We need to determine which value of
will give the correct line. We can begin with the point-slope form of an equation for a line, and then rewrite it in the slope-intercept form.
So
is parallel to
and passes through the point
Given the equation of a function and a point through which its graph passes, write the equation of a line parallel to the given line that passes through the given point.
Find a line parallel to the graph of
that passes through the point
The slope of the given line is 3. If we choose the slope-intercept form, we can substitute
and
into the slope-intercept form to find the y-intercept.
The line parallel to
that passes through
is
We can confirm that the two lines are parallel by graphing them. [link] shows that the two lines will never intersect.
We can use a very similar process to write the equation for a line perpendicular to a given line. Instead of using the same slope, however, we use the negative reciprocal of the given slope. Suppose we are given the function shown.
The slope of the line is 2, and its negative reciprocal is
Any function with a slope of
will be perpendicular to
So the lines formed by all of the following functions will be perpendicular to
As before, we can narrow down our choices for a particular perpendicular line if we know that it passes through a given point. Suppose then we want to write the equation of a line that is perpendicular to
and passes through the point
We already know that the slope is
Now we can use the point to find the y-intercept by substituting the given values into the slope-intercept form of a line and solving for
The equation for the function with a slope of
and a y-intercept of 2 is
So
is perpendicular to
and passes through the point
Be aware that perpendicular lines may not look obviously perpendicular on a graphing calculator unless we use the square zoom feature.
A horizontal line has a slope of zero and a vertical line has an undefined slope. These two lines are perpendicular, but the product of their slopes is not –1. Doesn’t this fact contradict the definition of perpendicular lines?
No. For two perpendicular linear functions, the product of their slopes is –1. However, a vertical line is not a function so the definition is not contradicted.
Given the equation of a function and a point through which its graph passes, write the equation of a line perpendicular to the given line.
and
from the coordinate pair provided into
Find the equation of a line perpendicular to
that passes through the point
The original line has slope
so the slope of the perpendicular line will be its negative reciprocal, or
Using this slope and the given point, we can find the equation of the line.
The line perpendicular to
that passes through
is
A graph of the two lines is shown in [link].
Note that that if we graph perpendicular lines on a graphing calculator using standard zoom, the lines may not appear to be perpendicular. Adjusting the window will make it possible to zoom in further to see the intersection more closely.
Given the function
write an equation for the line passing through
that is
a.
b.
Given two points on a line and a third point, write the equation of the perpendicular line that passes through the point.
A line passes through the points
and
Find the equation of a perpendicular line that passes through the point
From the two points of the given line, we can calculate the slope of that line.
Find the negative reciprocal of the slope.
We can then solve for the y-intercept of the line passing through the point
The equation for the line that is perpendicular to the line passing through the two given points and also passes through point
is
A line passes through the points,
and
Find the equation of a perpendicular line that passes through the point,
Access this online resource for additional instruction and practice with linear functions.
and initial value
See [link].
See [link].
and using the
that results. Similarly, the point-slope form of an equation can also be used. See [link].
Terry is skiing down a steep hill. Terry’s elevation,
in feet after
seconds is given by
Write a complete sentence describing Terry’s starting elevation and how it is changing over time.
Terry starts at an elevation of 3000 feet and descends 70 feet per second.
Jessica is walking home from a friend’s house. After 2 minutes she is 1.4 miles from home. Twelve minutes after leaving, she is 0.9 miles from home. What is her rate in miles per hour?
A boat is 100 miles away from the marina, sailing directly toward it at 10 miles per hour. Write an equation for the distance of the boat from the marina after t hours.
If the graphs of two linear functions are perpendicular, describe the relationship between the slopes and the y-intercepts.
If a horizontal line has the equation
and a vertical line has the equation
what is the point of intersection? Explain why what you found is the point of intersection.
The point of intersection is
This is because for the horizontal line, all of the
coordinates are
and for the vertical line, all of the
coordinates are
The point of intersection is on both lines and therefore will have these two characteristics.
For the following exercises, determine whether the equation of the curve can be written as a linear function.
Yes
Yes
No
Yes
For the following exercises, determine whether each function is increasing or decreasing.
Increasing
Decreasing
Decreasing
Increasing
Decreasing
For the following exercises, find the slope of the line that passes through the two given points.
and
and
2
and
and
–2
and
For the following exercises, given each set of information, find a linear equation satisfying the conditions, if possible.
and
and
Passes through
and
Passes through
and
Passes through
and
Passes through
and
x intercept at
and y intercept at
x intercept at
and y intercept at
For the following exercises, determine whether the lines given by the equations below are parallel, perpendicular, or neither.
perpendicular
parallel
For the following exercises, find the x- and y-intercepts of each equation.
For the following exercises, use the descriptions of each pair of lines given below to find the slopes of Line 1 and Line 2. Is each pair of lines parallel, perpendicular, or neither?
Line 1: Passes through
and
Line 2: Passes through
and
Line 1: m = –10 Line 2: m = –10 Parallel
Line 1: Passes through
and
Line 2: Passes through
and
Line 1: Passes through
and
Line 2: Passes through
and
Line 1: m = –2 Line 2: m = 1 Neither
Line 1: Passes through
and
Line 2: Passes through
and
Line 1: Passes through
and
Line 2: Passes through
and
For the following exercises, write an equation for the line described.
Write an equation for a line parallel to
and passing through the point
Write an equation for a line parallel to
and passing through the point
Write an equation for a line perpendicular to
and passing through the point
Write an equation for a line perpendicular to
and passing through the point
For the following exercises, find the slope of the line graphed.
0
For the following exercises, write an equation for the line graphed.
For the following exercises, match the given linear equation with its graph in [link].
F
C
A
For the following exercises, sketch a line with the given features.
An x-intercept of
and y-intercept of
An x-intercept
and y-intercept of
A y-intercept of
and slope
A y-intercept of
and slope
Passing through the points
and
Passing through the points
and
For the following exercises, sketch the graph of each equation.
For the following exercises, write the equation of the line shown in the graph.
For the following exercises, which of the tables could represent a linear function? For each that could be linear, find a linear equation that models the data.
0 | 5 | 10 | 15 |
5 | –10 | –25 | –40 |
Linear,
0 | 5 | 10 | 15 |
5 | 30 | 105 | 230 |
0 | 5 | 10 | 15 |
–5 | 20 | 45 | 70 |
Linear,
5 | 10 | 20 | 25 |
13 | 28 | 58 | 73 |
0 | 2 | 4 | 6 |
6 | –19 | –44 | –69 |
Linear,
2 | 4 | 8 | 10 |
13 | 23 | 43 | 53 |
2 | 4 | 6 | 8 |
–4 | 16 | 36 | 56 |
Linear,
0 | 2 | 6 | 8 |
6 | 31 | 106 | 231 |
For the following exercises, use a calculator or graphing technology to complete the task.
If
is a linear function,
find an equation for the function.
Graph the function
on a domain of
Enter the function in a graphing utility. For the viewing window, set the minimum value of
to be
and the maximum value of
to be
Graph the function
on a domain of
[link] shows the input,
and output,
for a linear function
a. Fill in the missing values of the table. b. Write the linear function
round to 3 decimal places.
w | –10 | 5.5 | 67.5 | b |
k | 30 | –26 | a | –44 |
[link] shows the input,
and output,
for a linear function
a. Fill in the missing values of the table. b. Write the linear function
p | 0.5 | 0.8 | 12 | b |
q | 400 | 700 | a | 1,000,000 |
Graph the linear function
on a domain of
for the function whose slope is
and y-intercept is
Label the points for the input values of
and
Graph the linear function
on a domain of
for the function whose slope is 75 and y-intercept is
Label the points for the input values of
and
Graph the linear function
where
on the same set of axes on a domain of
for the following values of
and
Find the value of
if a linear function goes through the following points and has the following slope:
Find the value of y if a linear function goes through the following points and has the following slope:
y = 175
Find the equation of the line that passes through the following points:
and
Find the equation of the line that passes through the following points:
and
Find the equation of the line that passes through the following points:
and
Find the equation of the line parallel to the line
through the point
y = –0.01x + 2.01
Find the equation of the line perpendicular to the line
through the point
For the following exercises, use the functions
Find the point of intersection of the lines
and
Where is
greater than
Where is
greater than
At noon, a barista notices that she has $20 in her tip jar. If she makes an average of $0.50 from each customer, how much will she have in her tip jar if she serves
more customers during her shift?
A gym membership with two personal training sessions costs $125, while gym membership with five personal training sessions costs $260. What is cost per session?
A clothing business finds there is a linear relationship between the number of shirts,
it can sell and the price,
it can charge per shirt. In particular, historical data shows that 1,000 shirts can be sold at a price of
while 3,000 shirts can be sold at a price of $22. Find a linear equation in the form
that gives the price
they can charge for
shirts.
A phone company charges for service according to the formula:
where
is the number of minutes talked, and
is the monthly charge, in dollars. Find and interpret the rate of change and initial value.
A farmer finds there is a linear relationship between the number of bean stalks,
she plants and the yield,
each plant produces. When she plants 30 stalks, each plant yields 30 oz of beans. When she plants 34 stalks, each plant produces 28 oz of beans. Find a linear relationships in the form
that gives the yield when
stalks are planted.
A city’s population in the year 1960 was 287,500. In 1989 the population was 275,900. Compute the rate of growth of the population and make a statement about the population rate of change in people per year.
A town’s population has been growing linearly. In 2003, the population was 45,000, and the population has been growing by 1,700 people each year. Write an equation,
for the population
years after 2003.
Suppose that average annual income (in dollars) for the years 1990 through 1999 is given by the linear function:
where
is the number of years after 1990. Which of the following interprets the slope in the context of the problem?
When temperature is 0 degrees Celsius, the Fahrenheit temperature is 32. When the Celsius temperature is 100, the corresponding Fahrenheit temperature is 212. Express the Fahrenheit temperature as a linear function of
the Celsius temperature,
where
is a real number. The slope of a horizontal line is 0.
where
is a real number. The slope of a vertical line is undefined.
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