In this section you will:
Caroline is a full-time college student planning a spring break vacation. To earn enough money for the trip, she has taken a part-time job at the local bank that pays $15.00/hr, and she opened a savings account with an initial deposit of $400 on January 15. She arranged for direct deposit of her payroll checks. If spring break begins March 20 and the trip will cost approximately $2,500, how many hours will she have to work to earn enough to pay for her vacation? If she can only work 4 hours per day, how many days per week will she have to work? How many weeks will it take? In this section, we will investigate problems like this and others, which generate graphs like the line in [link].
A linear equation is an equation of a straight line, written in one variable. The only power of the variable is 1. Linear equations in one variable may take the form
and are solved using basic algebraic operations.
We begin by classifying linear equations in one variable as one of three types: identity, conditional, or inconsistent. An identity equation is true for all values of the variable. Here is an example of an identity equation.
The solution set consists of all values that make the equation true. For this equation, the solution set is all real numbers because any real number substituted for
will make the equation true.
A conditional equation is true for only some values of the variable. For example, if we are to solve the equation
we have the following:
The solution set consists of one number:
It is the only solution and, therefore, we have solved a conditional equation.
An inconsistent equation results in a false statement. For example, if we are to solve
we have the following:
Indeed,
There is no solution because this is an inconsistent equation.
Solving linear equations in one variable involves the fundamental properties of equality and basic algebraic operations. A brief review of those operations follows.
A linear equation in one variable can be written in the form
where a and b are real numbers,
Given a linear equation in one variable, use algebra to solve it.
The following steps are used to manipulate an equation and isolate the unknown variable, so that the last line reads
if x is the unknown. There is no set order, as the steps used depend on what is given:
Solve the following equation:
This equation can be written in the form
by subtracting
from both sides. However, we may proceed to solve the equation in its original form by performing algebraic operations.
The solution is 6
Solve the linear equation in one variable:
Solve the following equation:
Apply standard algebraic properties.
This problem requires the distributive property to be applied twice, and then the properties of algebra are used to reach the final line,
Solve the equation in one variable:
In this section, we look at rational equations that, after some manipulation, result in a linear equation. If an equation contains at least one rational expression, it is a considered a rational equation.
Recall that a rational number is the ratio of two numbers, such as
or
A rational expression is the ratio, or quotient, of two polynomials. Here are three examples.
Rational equations have a variable in the denominator in at least one of the terms. Our goal is to perform algebraic operations so that the variables appear in the numerator. In fact, we will eliminate all denominators by multiplying both sides of the equation by the least common denominator (LCD).
Finding the LCD is identifying an expression that contains the highest power of all of the factors in all of the denominators. We do this because when the equation is multiplied by the LCD, the common factors in the LCD and in each denominator will equal one and will cancel out.
Solve the rational equation:
We have three denominators;
and 3. The LCD must contain
and 3. An LCD of
contains all three denominators. In other words, each denominator can be divided evenly into the LCD. Next, multiply both sides of the equation by the LCD
A common mistake made when solving rational equations involves finding the LCD when one of the denominators is a binomial—two terms added or subtracted—such as
Always consider a binomial as an individual factor—the terms cannot be separated. For example, suppose a problem has three terms and the denominators are
and
First, factor all denominators. We then have
and
as the denominators. (Note the parentheses placed around the second denominator.) Only the last two denominators have a common factor of
The
in the first denominator is separate from the
in the
denominators. An effective way to remember this is to write factored and binomial denominators in parentheses, and consider each parentheses as a separate unit or a separate factor. The LCD in this instance is found by multiplying together the
one factor of
and the 3. Thus, the LCD is the following:
So, both sides of the equation would be multiplied by
Leave the LCD in factored form, as this makes it easier to see how each denominator in the problem cancels out.
Another example is a problem with two denominators, such as
and
Once the second denominator is factored as
there is a common factor of x in both denominators and the LCD is
Sometimes we have a rational equation in the form of a proportion; that is, when one fraction equals another fraction and there are no other terms in the equation.
We can use another method of solving the equation without finding the LCD: cross-multiplication. We multiply terms by crossing over the equal sign.
Multiply
and
which results in
Any solution that makes a denominator in the original expression equal zero must be excluded from the possibilities.
A rational equation contains at least one rational expression where the variable appears in at least one of the denominators.
Given a rational equation, solve it.
Solve the following rational equation:
We have three denominators:
and
No factoring is required. The product of the first two denominators is equal to the third denominator, so, the LCD is
Only one value is excluded from a solution set, 0.
Next, multiply the whole equation (both sides of the equal sign) by
The proposed solution is −1,
which is not an excluded value, so the solution set contains one number,
or
written in set notation.
Solve the rational equation:
Solve the following rational equation:
First find the common denominator. The three denominators in factored form are
and
The smallest expression that is divisible by each one of the denominators is
Only
is an excluded value. Multiply the whole equation by
The solution is
Solve the rational equation:
Solve the following rational equations and state the excluded values:
The denominators
and
have nothing in common. Therefore, the LCD is the product
However, for this problem, we can cross-multiply.
The solution is 15.
The excluded values are
and
The LCD is
Multiply both sides of the equation by
The solution is
The excluded value is
The least common denominator is
Multiply both sides of the equation by
The solution is 4. The excluded value is
Solve
State the excluded values.
Excluded values are
and
Solve the rational equation after factoring the denominators:
State the excluded values.
We must factor the denominator
We recognize this as the difference of squares, and factor it as
Thus, the LCD that contains each denominator is
Multiply the whole equation by the LCD, cancel out the denominators, and solve the remaining equation.
The solution is
The excluded values are
and
Solve the rational equation:
Perhaps the most familiar form of a linear equation is the slope-intercept form, written as
where
and
Let us begin with the slope.
The slope of a line refers to the ratio of the vertical change in y over the horizontal change in x between any two points on a line. It indicates the direction in which a line slants as well as its steepness. Slope is sometimes described as rise over run.
If the slope is positive, the line slants to the right. If the slope is negative, the line slants to the left. As the slope increases, the line becomes steeper. Some examples are shown in [link]. The lines indicate the following slopes:
and
The slope of a line, m, represents the change in y over the change in x. Given two points,
and
the following formula determines the slope of a line containing these points:
Find the slope of a line that passes through the points
and
We substitute the y-values and the x-values into the formula.
The slope is
It does not matter which point is called
or
As long as we are consistent with the order of the y terms and the order of the x terms in the numerator and denominator, the calculation will yield the same result.
Find the slope of the line that passes through the points
and
Identify the slope and y-intercept, given the equation
As the line is in
form, the given line has a slope of
The y-intercept is
The y-intercept is the point at which the line crosses the y-axis. On the y-axis,
We can always identify the y-intercept when the line is in slope-intercept form, as it will always equal b. Or, just substitute
and solve for y.
Given the slope and one point on a line, we can find the equation of the line using the point-slope formula.
This is an important formula, as it will be used in other areas of college algebra and often in calculus to find the equation of a tangent line. We need only one point and the slope of the line to use the formula. After substituting the slope and the coordinates of one point into the formula, we simplify it and write it in slope-intercept form.
Given one point and the slope, the point-slope formula will lead to the equation of a line:
Write the equation of the line with slope
and passing through the point
Write the final equation in slope-intercept form.
Using the point-slope formula, substitute
for m and the point
for
Note that any point on the line can be used to find the equation. If done correctly, the same final equation will be obtained.
Given
find the equation of the line in slope-intercept form passing through the point
Find the equation of the line passing through the points
and
Write the final equation in slope-intercept form.
First, we calculate the slope using the slope formula and two points.
Next, we use the point-slope formula with the slope of
and either point. Let’s pick the point
for
In slope-intercept form, the equation is written as
To prove that either point can be used, let us use the second point
and see if we get the same equation.
We see that the same line will be obtained using either point. This makes sense because we used both points to calculate the slope.
Another way that we can represent the equation of a line is in standard form. Standard form is given as
where
and
are integers. The x- and y-terms are on one side of the equal sign and the constant term is on the other side.
Find the equation of the line with
and passing through the point
Write the equation in standard form.
We begin using the point-slope formula.
From here, we multiply through by 2, as no fractions are permitted in standard form, and then move both variables to the left aside of the equal sign and move the constants to the right.
This equation is now written in standard form.
Find the equation of the line in standard form with slope
and passing through the point
The equations of vertical and horizontal lines do not require any of the preceding formulas, although we can use the formulas to prove that the equations are correct. The equation of a vertical line is given as
where c is a constant. The slope of a vertical line is undefined, and regardless of the y-value of any point on the line, the x-coordinate of the point will be c.
Suppose that we want to find the equation of a line containing the following points:
and
First, we will find the slope.
Zero in the denominator means that the slope is undefined and, therefore, we cannot use the point-slope formula. However, we can plot the points. Notice that all of the x-coordinates are the same and we find a vertical line through
See [link].
The equation of a horizontal line is given as
where c is a constant. The slope of a horizontal line is zero, and for any x-value of a point on the line, the y-coordinate will be c.
Suppose we want to find the equation of a line that contains the following set of points:
and
We can use the point-slope formula. First, we find the slope using any two points on the line.
Use any point for
in the formula, or use the y-intercept.
The graph is a horizontal line through
Notice that all of the y-coordinates are the same. See [link].
Find the equation of the line passing through the given points:
and
The x-coordinate of both points is 1. Therefore, we have a vertical line,
Find the equation of the line passing through
and
Horizontal line:
Parallel lines have the same slope and different y-intercepts. Lines that are parallel to each other will never intersect. For example, [link] shows the graphs of various lines with the same slope,
All of the lines shown in the graph are parallel because they have the same slope and different y-intercepts.
Lines that are perpendicular intersect to form a
-angle. The slope of one line is the negative reciprocal of the other. We can show that two lines are perpendicular if the product of the two slopes is
For example, [link] shows the graph of two perpendicular lines. One line has a slope of 3; the other line has a slope of
Graph the equations of the given lines, and state whether they are parallel, perpendicular, or neither:
and
The first thing we want to do is rewrite the equations so that both equations are in slope-intercept form.
First equation:
Second equation:
See the graph of both lines in [link]
From the graph, we can see that the lines appear perpendicular, but we must compare the slopes.
The slopes are negative reciprocals of each other, confirming that the lines are perpendicular.
Graph the two lines and determine whether they are parallel, perpendicular, or neither:
and
Parallel lines: equations are written in slope-intercept form.
As we have learned, determining whether two lines are parallel or perpendicular is a matter of finding the slopes. To write the equation of a line parallel or perpendicular to another line, we follow the same principles as we do for finding the equation of any line. After finding the slope, use the point-slope formula to write the equation of the new line.
Given an equation for a line, write the equation of a line parallel or perpendicular to it.
Write the equation of line parallel to a
and passing through the point
First, we will write the equation in slope-intercept form to find the slope.
The slope is
The y-intercept is
but that really does not enter into our problem, as the only thing we need for two lines to be parallel is the same slope. The one exception is that if the y-intercepts are the same, then the two lines are the same line. The next step is to use this slope and the given point with the point-slope formula.
The equation of the line is
See [link].
Find the equation of the line parallel to
and passing through the point
Find the equation of the line perpendicular to
and passing through the point
The first step is to write the equation in slope-intercept form.
We see that the slope is
This means that the slope of the line perpendicular to the given line is the negative reciprocal, or
Next, we use the point-slope formula with this new slope and the given point.
Access these online resources for additional instruction and practice with linear equations.
where c is a constant.
where c is a constant. See [link].
What does it mean when we say that two lines are parallel?
It means they have the same slope.
What is the relationship between the slopes of perpendicular lines (assuming neither is horizontal nor vertical)?
How do we recognize when an equation, for example
will be a straight line (linear) when graphed?
The exponent of the
variable is 1. It is called a first-degree equation.
What does it mean when we say that a linear equation is inconsistent?
When solving the following equation:
explain why we must exclude
and
as possible solutions from the solution set.
If we insert either value into the equation, they make an expression in the equation undefined (zero in the denominator).
For the following exercises, solve the equation for
For the following exercises, solve each rational equation for
State all x-values that are excluded from the solution set.
when we solve this we get
which is excluded, therefore NO solution
For the following exercises, find the equation of the line using the point-slope formula.
Write all the final equations using the slope-intercept form.
with a slope of
with a slope of
x-intercept is 1, and
y-intercept is 2, and
and
parallel to
and passes through the point
perpendicular to
and passes through the point
.
For the following exercises, find the equation of the line using the given information.
and
and
The slope is undefined and it passes through the point
The slope equals zero and it passes through the point
The slope is
and it passes through the point
and
For the following exercises, graph the pair of equations on the same axes, and state whether they are parallel, perpendicular, or neither.
Parallel
Perpendicular
For the following exercises, find the slope of the line that passes through the given points.
and
and
and
and
and
For the following exercises, find the slope of the lines that pass through each pair of points and determine whether the lines are parallel or perpendicular.
For the following exercises, express the equations in slope intercept form (rounding each number to the thousandths place). Enter this into a graphing calculator as Y1, then adjust the ymin and ymax values for your window to include where the y-intercept occurs. State your ymin and ymax values.
Answers may vary.
Answers may vary.
Starting with the point-slope formula
solve this expression for
in terms of
and
Starting with the standard form of an equation
solve this expression for y in terms of
and
Then put the expression in slope-intercept form.
Use the above derived formula to put the following standard equation in slope intercept form:
Given that the following coordinates are the vertices of a rectangle, prove that this truly is a rectangle by showing the slopes of the sides that meet are perpendicular.
and
Yes they are perpendicular.
Find the slopes of the diagonals in the previous exercise. Are they perpendicular?
The slope for a wheelchair ramp for a home has to be
If the vertical distance from the ground to the door bottom is 2.5 ft, find the distance the ramp has to extend from the home in order to comply with the needed slope.
30 ft
If the profit equation for a small business selling
number of item one and
number of item two is
find the
value when
For the following exercises, use this scenario: The cost of renting a car is $45/wk plus $0.25/mi traveled during that week. An equation to represent the cost would be
where
is the number of miles traveled.
What is your cost if you travel 50 mi?
$57.50
If your cost were
how many miles were you charged for traveling?
Suppose you have a maximum of $100 to spend for the car rental. What would be the maximum number of miles you could travel?
220 mi
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