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Study Guides > Boundless Algebra

Introduction to Linear Functions

What is a Linear Function?

Linear functions are algebraic equations whose graphs are straight lines with unique values for their slope and y-intercepts.

Learning Objectives

Describe the parts and characteristics of a linear function

Key Takeaways

Key Points

  • A linear function is an algebraic equation in which each term is either a constant or the product of a constant and (the first power of) a single variable.
  • A function is a relation with the property that each input is related to exactly one output.
  • A relation is a set of ordered pairs.
  • The graph of a linear function is a straight line, but a vertical line is not the graph of a function.
  • All linear functions are written as equations and are characterized by their slope and yy-intercept.

Key Terms

  • relation: A collection of ordered pairs.
  • variable: A symbol that represents a quantity in a mathematical expression, as used in many sciences.
  • linear function: An algebraic equation in which each term is either a constant or the product of a constant and (the first power of) a single variable.
  • function: A relation between a set of inputs and a set of permissible outputs with the property that each input is related to exactly one output.

What is a Linear Function?

A linear function is an algebraic equation in which each term is either a constant or the product of a constant and (the first power of) a single variable. For example, a common equation, y=mx+by=mx+b, (namely the slope-intercept form, which we will learn more about later) is a linear function because it meets both criteria with xx and yy as variables and mm and bb as constants.  It is linear: the exponent of the xx term is a one (first power), and it follows the definition of a function: for each input (xx) there is exactly one output (yy).  Also, its graph is a straight line.

Graphs of Linear Functions

The origin of the name "linear" comes from the fact that the set of solutions of such an equation forms a straight line in the plane. In the linear function graphs below, the constant, mm, determines the slope or gradient of that line, and the constant term, bb, determines the point at which the line crosses the yy-axis, otherwise known as the yy-intercept.
image Graphs of linear functions: The blue line, y=12x3y=\frac{1}{2}x-3 and the red line, y=x+5y=-x+5 are both linear functions.  The blue line has a positive slope of 12\frac{1}{2} and a yy-intercept of 3-3; the red line has a negative slope of 1-1 and a yy-intercept of 55.

Vertical and Horizontal Lines

Vertical lines have an undefined slope, and cannot be represented in the form y=mx+by=mx+b, but instead as an equation of the form x=cx=c for a constant cc, because the vertical line intersects a value on the xx-axis, cc.  For example, the graph of the equation x=4x=4 includes the same input value of 44 for all points on the line, but would have different output values, such as (4,2),(4,0),(4,1),(4,5),(4,-2),(4,0),(4,1),(4,5), etcetera. Vertical lines are NOT functions, however, since each input is related to more than one output. Horizontal lines have a slope of zero and is represented by the form, y=by=b, where bb is the yy-intercept.  A graph of the equation y=6y=6 includes the same output value of 6 for all input values on the line, such as (2,6),(0,6),(2,6),(6,6)(-2,6),(0,6),(2,6),(6,6), etcetera.  Horizontal lines ARE functions because the relation (set of points) has the characteristic that each input is related to exactly one output.

Slope

Slope describes the direction and steepness of a line, and can be calculated given two points on the line.

Learning Objectives

Calculate the slope of a line using "rise over run" and identify the role of slope in a linear equation

Key Takeaways

Key Points

  • The slope of a line is a number that describes both the direction and the steepness of the line; its sign indicates the direction, while its magnitude indicates the steepness.
  • The ratio of the rise to the run is the slope of a line, m=riserunm = \frac{rise}{run}.
  • The slope of a line can be calculated with the formula m=y2y1x2x1m = \frac{y_{2} - y_{1}}{x_{2} - x_{1}}, where (x1,y1)(x_1, y_1) and (x2,y2)(x_2, y_2) are points on the line.

Key Terms

  • steepness: The rate at which a function is deviating from a reference.
  • direction: Increasing, decreasing, horizontal or vertical.

Slope

In mathematics, the slope of a line is a number that describes both the direction and the steepness of the line. Slope is often denoted by the letter mm. Recall the slop-intercept form of a line, y=mx+by = mx + b. Putting the equation of a line into this form gives you the slope (mm) of a line, and its yy-intercept (bb). We will now discuss the interpretation of mm, and how to calculate mm for a given line. The direction of a line is either increasing, decreasing, horizontal or vertical. A line is increasing if it goes up from left to right which implies that the slope is positive (m>0m > 0). A line is decreasing if it goes down from left to right and the slope is negative (m<0m < 0). If a line is horizontal the slope is zero and is a constant function (y=cy=c). If a line is vertical the slope is undefined.
A positive slope goes up and to the right, a negative slope goes down and to the right. Zero slope is a horizontal line, and a vertical line has undefined slope. Slopes of Lines: The slope of a line can be positive, negative, zero, or undefined.

The steepness, or incline, of a line is measured by the absolute value of the slope. A slope with a greater absolute value indicates a steeper line. In other words, a line with a slope of 9-9 is steeper than a line with a slope of 77.

Calculating Slope

Slope is calculated by finding the ratio of the "vertical change" to the "horizontal change" between any two distinct points on a line. This ratio is represented by a quotient ("rise over run"), and gives the same number for any two distinct points on the same line. It is represented by m=riserunm = \frac{rise}{run}.
The rise is how much the line goes up, and the run is how much the line goes to the right. Visualization of Slope: The slope of a line is calculated as "rise over run."

Mathematically, the slope m of the line is:

m=y2y1x2x1\displaystyle m = \frac{y_{2} - y_{1}}{x_{2} - x_{1}} Two points on the line are required to find mm. Given two points (x1,y1)(x_1, y_1) and (x2,y2)(x_2, y_2), take a look at the graph below and note how the "rise" of slope is given by the difference in the yy-values of the two points, and the "run" is given by the difference in the xx-values.
The points (x1, y1) and (x2, y2) are shown on a line. The second point is higher than the first point and to the right of it. The difference in height between the points is given by y2-y1, the rise, and the difference in horizontal direction between the points is given by x2-x1, the run. Slope Represented Graphically: The slope m=y2y1x2x1m =\frac{y_{2} - y_{1}}{x_{2} - x_{1}} is calculated from the two points (x1,y1)\left( x_1,y_1 \right) and (x2,y2)\left( x_2,y_2 \right).

Now we’ll look at some graphs on a coordinate grid to find their slopes. In many cases, we can find slope by simply counting out the rise and the run. We start by locating two points on the line. If possible, we try to choose points with coordinates that are integers to make our calculations easier.

Example

Find the slope of the line shown on the coordinate plane below.
A line with positive slope that passes through the points (0, -3) and (5, 1). Find the slope of the line: Notice the line is increasing so make sure to look for a slope that is positive.

Locate two points on the graph, choosing points whose coordinates are integers. We will use (0,3)(0, -3) and (5,1)(5, 1). Starting with the point on the left, (0,3)(0, -3), sketch a right triangle, going from the first point to the second point, (5,1)(5, 1).

The same line as above, but with the point (0, 1) marked. The distance from the given points to this point will give the rise and the run. From (0, -3) to (0, 1) is 4 units (the rise, as the change is in the y direction), and from (0, 1) to (5, 1) is five units (the run, as the change is in the x direction). Identify points on the line: Draw a triangle to help identify the rise and run.

Count the rise on the vertical leg of the triangle: 44 units.

Count the run on the horizontal leg of the triangle: 55 units. Use the slope formula to take the ratio of rise over run: \displaystyle \begin{align} m &= \frac{rise}{run} \\ &= \frac{4}{5} \end{align} The slope of the line is 45\frac{4}{5}. Notice that the slope is positive since the line slants upward from left to right.

Example

Find the slope of the line shown on the coordinate plane below.
A line with a negative slope passing through the points (0, 5) and (3, 3). Find the slope of the line: We can see the slope is decreasing, so be sure to look for a negative slope.

Locate two points on the graph. Look for points with coordinates that are integers. We can choose any points, but we will use (0,5)(0, 5) and (3,3)(3, 3).

The line above with the point (0, 3) marked, to make a right triangle with the points noted above. The legs of the right triangle are the rise and the run. Identify two points on the line: The points (0,5)(0, 5) and (3,3)(3, 3) are on the line.
m=y2y1x2x1\displaystyle m =\frac{y_{2} - y_{1}}{x_{2} - x_{1}} Let (x1,y1)(x_1, y_1) be the point (0,5)(0, 5), and (x2,y2)(x_2, y_2) be the point (3,3)(3, 3). Plugging the corresponding values into the slope formula, we get: \displaystyle \begin{align} m &= \frac{3-5}{3-0} \\ &= \frac{-2}{3} \end{align} The slope of the line is 23- \frac{2}{3}. Notice that the slope is negative since the line slants downward from left to right.

Direct and Inverse Variation

Two variables in direct variation have a linear relationship, while variables in inverse variation do not.

Learning Objectives

Recognize examples of functions that vary directly and inversely

Key Takeaways

Key Points

  • Two variables that change proportionally to one another are said to be in direct variation.
  • The relationship between two directly proportionate variable can be represented by a linear equation in slope -intercept form, and is easily modeled using a linear graph.
  • Inverse variation is the opposite of direct variation; two variables are said to be inversely proportional when a change is performed on one variable and the opposite happens to the other.
  • The relationship between two inversely proportionate variables cannot be represented by a linear equation, and its graphical representation is not a line, but a hyperbola.

Key Terms

  • hyperbola: A conic section formed by the intersection of a cone with a plane that intersects the base of the cone and is not tangent to the cone.
  • proportional: At a constant ratio. Two magnitudes (numbers) are said to be proportional if the second varies in a direct relation arithmetically to the first.

Direct Variation

Simply put, two variables are in direct variation when the same thing that happens to one variable happens to the other. If xx and yy are in direct variation, and xx is doubled, then yy would also be doubled. The two variables may be considered directly proportional. For example, a toothbrush costs 22 dollars. Purchasing 55 toothbrushes would cost 1010 dollars, and purchasing 1010 toothbrushes would 2020 cost dollars. Thus we can say that the cost varies directly as the value of toothbrushes. Direct variation is represented by a linear equation, and can be modeled by graphing a line. Since we know that the relationship between two values is constant, we can give their relationship with: yx=k\displaystyle \frac{y}{x} = k Where kk is a constant. Rewriting this equation by multiplying both sides by xx yields: y=kx\displaystyle y = kx Notice that this is a linear equation in slope-intercept form, where the yy-intercept bb is equal to 00. Thus, any line passing through the origin represents a direct variation between xx and yy:
image Directly Proportional Variables: The graph of y=kxy = kx demonstrates an example of direct variation between two variables.

Revisiting the example with toothbrushes and dollars, we can define the xx-axis as number of toothbrushes and the yy-axis as number of dollars. Doing so, the variables would abide by the relationship:

yx=2\displaystyle \frac{y}{x} = 2 Any augmentation of one variable would lead to an equal augmentation of the other. For example, doubling yy would result in the doubling of xx.

Inverse Variation

Inverse variation is the opposite of direct variation. In the case of inverse variation, the increase of one variable leads to the decrease of another. In fact, two variables are said to be inversely proportional when an operation of change is performed on one variable and the opposite happens to the other. For example, if xx and yy are inversely proportional, if xx is doubled, then yy is halved. As an example, the time taken for a journey is inversely proportional to the speed of travel. If your car travels at a greater speed, the journey to your destination will be shorter. Knowing that the relationship between the two variables is constant, we can show that their relationship is: yx=k\displaystyle yx = k Where kk is a constant known as the constant of proportionality. Note that as long as kk is not equal to 00, neither xx nor yy can ever equal 00 either. We can rearrange the above equation to place the variables on opposite sides: y=kx\displaystyle y=\frac{k}{x} Notice that this is not a linear equation. It is impossible to put it in slope-intercept form. Thus, an inverse relationship cannot be represented by a line with constant slope. Inverse variation can be illustrated with a graph in the shape of a hyperbola, pictured below.
A curve in two parts, with the x and y axes as asymptotes. One part of the curve is in the third quadrant, decreasing from the x axis to negative infinity at the y axis. The other part of the curve is in the first quadrant, decreasing from positive infinity to zero along the x axis. Inversely Proportional Function: An inversely proportional relationship between two variables is represented graphically by a hyperbola.

Zeroes of Linear Functions

A zero, or xx-intercept, is the point at which a linear function's value will equal zero.

Learning Objectives

Practice finding the zeros of linear functions

Key Takeaways

Key Points

  • A zero is a point at which a function 's value will be equal to zero. Its coordinates are (x,0)(x,0), where xx is equal to the zero of the graph.
  • Zeros can be observed graphically or solved for algebraically.
  • A linear function can have none, one, or infinitely many zeros. If the function is a horizontal line ( slope = 00), it will have no zeros unless its equation is y=0y=0, in which case it will have infinitely many. If the line is non-horizontal, it will have one zero.

Key Terms

  • zero: Also known as a root; an xx value at which the function of xx is equal to 00.
  • linear function: An algebraic equation in which each term is either a constant or the product of a constant and (the first power of) a single variable.
  • y-intercept: A point at which a line crosses the yy-axis of a Cartesian grid.
The graph of a linear function is a straight line. Graphically, where the line crosses the xx-axis, is called a zero, or root.  Algebraically, a zero is an xx value at which the function of xx is equal to 00.  Linear functions can have none, one, or infinitely many zeros.  If there is a horizontal line through any point on the yy-axis, other than at zero, there are no zeros, since the line will never cross the xx-axis.  If the horizontal line overlaps the xx-axis, (goes through the yy-axis at zero) then there are infinitely many zeros, since the line intersects the xx-axis multiple times.  Finally, if the line is vertical or has a slope, then there will be only one zero.

Finding the Zeros of Linear Functions Graphically

Zeros can be observed graphically.  An xx-intercept, or zero, is a property of many functions. Because the xx-intercept (zero) is a point at which the function crosses the xx-axis, it will have the value (x,0)(x,0), where xx is the zero. All lines, with a value for the slope, will have one zero.  To find the zero of a linear function, simply find the point where the line crosses the xx-axis.
image Zeros of linear functions: The blue line, y=12x+2y=\frac{1}{2}x+2, has a zero at (4,0)(-4,0); the red line, y=x+5y=-x+5, has a zero at (5,0)(5,0).  Since each line has a value for the slope, each line has exactly one zero.

Finding the Zeros of Linear Functions Algebraically

To find the zero of a linear function algebraically, set y=0y=0 and solve for xx. The zero from solving the linear function above graphically must match solving the same function algebraically.

Example: Find the zero of y=12x+2y=\frac{1}{2}x+2 algebraically

First, substitute 00 for yy: 0=12x+2\displaystyle 0=\frac{1}{2}x+2 Next, solve for xx. Subtract 22 and then multiply by 22, to obtain: \displaystyle \begin{align} \frac{1}{2}x&=-2\\ x&=-4 \end{align} The zero is (4,0)(-4,0).  This is the same zero that was found using the graphing method.

Slope-Intercept Equations

The slope-intercept form of a line summarizes the information necessary to quickly construct its graph.

Learning Objectives

Convert linear equations to slope-intercept form and explain why it is useful

Key Takeaways

Key Points

  • The slope -intercept form of a line is given by y=mx+by = mx + b where mm is the slope of the line and bb is the yy-intercept.
  • The constant bb is known as the yy-intercept.  From slope- intercept form, when x=0x=0, y=by=b, and the point (0,b)(0,b) is the unique point on the line also on the yy-axis.
  • To graph a line in slope-intercept form, first plot the yy-intercept, then use the value of the slope to locate a second point on the line.  If the value of the slope is an integer, use a 11 for the denominator.
  • Use algebra to solve for yy if the equation is not written in slope-intercept form. Only then can the value of the slope and yy-intercept be located from the equation accurately.

Key Terms

  • slope: The ratio of the vertical and horizontal distances between two points on a line; zero if the line is horizontal, undefined if it is vertical.
  • y-intercept: A point at which a line crosses the yy-axis of a Cartesian grid.

Slope-Intercept Form

One of the most common representations for a line is with the slope-intercept form. Such an equation is given by y=mx+by=mx+b, where xx and yy are variables and mm and bb are constants.  When written in this form, the constant mm is the value of the slope and bb is the yy-intercept.  Note that if mm is 00, then y=by=b represents a horizontal line. Note that this equation does not allow for vertical lines, since that would require that mm be infinite (undefined).  However, a vertical line is defined by the equation x=cx=c for some constant cc.

Converting an Equation to Slope-Intercept Form

Writing an equation in slope-intercept form is valuable since from the form it is easy to identify the slope and yy-intercept.  This assists in finding solutions to various problems, such as graphing, comparing two lines to determine if they are parallel or perpendicular and solving a system of equations.

Example

Let's write an equation in slope-intercept form with m=23m=-\frac{2}{3}, and b=3b=3.  Simply substitute the values into the slope-intercept form to obtain: y=23x+3\displaystyle y=-\frac{2}{3}x+3 If an equation is not in slope-intercept form, solve for yy and rewrite the equation.

Example

Let's write the equation 3x+2y=43x+2y=-4 in slope-intercept form and identify the slope and yy-intercept. To solve the equation for yy, first subtract 3x3x from both sides of the equation to get: 2y=3x4\displaystyle 2y=-3x-4 Then divide both sides of the equation by 22 to obtain: y=12(3x4)\displaystyle y=\frac{1}{2}(-3x-4) Which simplifies to y=32x2y=-\frac{3}{2}x-2.  Now that the equation is in slope-intercept form, we see that the slope m=32m=-\frac{3}{2}, and the yy-intercept b=2b=-2.

Graphing an Equation in Slope-Intercept Form

We begin by constructing the graph of the equation in the previous example.

Example

We construct the graph the line y=32x2y=-\frac{3}{2}x-2 using the slope-intercept method. We begin by plotting the yy-intercept b=2b=-2, whose coordinates are (0,2)(0,-2).  The value of the slope dictates where to place the next point. Since the value of the slope is 32\frac{-3}{2}, the rise is 3-3 and the run is 22.  This means that from the yy-intercept, (0,2)(0,-2), move 33 units down, and move 22 units right.  Thus we arrive at the point (2,5)(2,-5) on the line. If the negative sign is placed with the denominator instead the slope would be written as 32\frac{3}{-2}, we can instead move up 33 units and left 22 units from the yy-intercept to arrive at the point (2,1)(-2,1), also on the line.
image Slope-intercept graph: Graph of the line y=32x2y=-\frac{3}{2}x-2.

Example

Let's graph the equation 12x6y6=012x-6y-6=0. First we solve the equation for yy by subtracting 12x12x to obtain: 6y6=12x\displaystyle -6y-6=-12x Next, add 66 to get: 6y=12x+6\displaystyle -6y=-12x+6 Finally, divide all terms by 6-6 to get the slope-intercept form: y=2x1\displaystyle y=2x-1 The slope is 22, and the yy-intercept is 1-1.  Using this information, graphing is easy.  Start by plotting the yy-intercept (0,1)(0,-1), then use the value of the slope, 21\frac{2}{1}, to move up 22 units and right 11 unit.
The line has positive slope and goes through the points ((0, -1) and (1, 1) Slope-intercept graph: Graph of the line y=2x1y=2x-1.

Point-Slope Equations

The point-slope equation is another way to represent a line; only the slope and a single point are needed.

Learning Objectives

Use point-slope form to find the equation of a line passing through two points and verify that it is equivalent to the slope-intercept form of the equation

Key Takeaways

Key Points

  • The point - slope equation is given by yy1=m(xx1)y-y_{1}=m(x-x_{1}), where (x1,y1)(x_{1}, y_{1}) is any point on the line, and mm is the slope of the line.
  • The point-slope equation requires that there is at least one point and the slope. If there are two points and no slope, the slope can be calculated from the two points first and then choose one of the two points to write the equation.
  • The point-slope equation and slope-intercept equations are equivalent.  It can be shown that given a point (x1,y1)(x_{1}, y_{1}) and slope mm, the yy-intercept (bb) in the slope-intercept equation is y1mx1y_{1}-mx_{1}.

Key Terms

  • point-slope equation: An equation of a line given a point (x1,y1)(x_{1}, y_{1}) and a slope mm: yy1=m(xx1) y-y_{1}=m(x-x_{1}).
 

Point-Slope Equation

The point-slope equation is a way of describing the equation of a line. The point-slope form is ideal if you are given the slope and only one point, or if you are given two points and do not know what the yy-intercept is. Given a slope, mm, and a point (x1,y1)(x_{1}, y_{1}), the point-slope equation is: yy1=m(xx1)\displaystyle y-y_{1}=m(x-x_{1})

Verify Point-Slope Form is Equivalent to Slope-Intercept Form

To show that these two equations are equivalent, choose a generic point (x1,y1)(x_{1}, y_{1}). Plug in the generic point into the equation y=mx+by=mx+b.  The equation is now, y1=mx1+by_{1}=mx_{1}+b, giving us the ordered pair,(x1,mx1+b)(x_{1}, mx_{1}+b). Then plug this point into the point-slope equation and solve for yy to get: y(mx1+b)=m(xx1)\displaystyle y-(mx_{1}+b)=m(x-x_{1}) Distribute the negative sign through and distribute mm through (xx1)(x-x_{1}): ymx1b=mxmx1\displaystyle y-mx_{1}-b=mx-mx_{1} Add mx1mx_{1} to both sides: ymx1+mx1b=mxmx1+mx1\displaystyle y-mx_{1}+mx_{1}-b=mx-mx_{1}+mx_{1} Combine like terms: yb=mx\displaystyle y-b=mx Add bb to both sides: yb+b=mx+b\displaystyle y-b+b=mx+b Combine like terms: y=mx+b\displaystyle y=mx+b Therefore, the two equations are equivalent and either one can express an equation of a line depending on what information is given in the problem or what type of equation is requested in the problem.

Example: Write the equation of a line in point-slope form, given a point (2,1)(2,1) and slope 4-4, and convert to slope-intercept form

Write the equation of the line in point-slope form: y1=4(x2)\displaystyle y-1=-4(x-2) To switch this equation into slope-intercept form, solve the equation for yy: y1=4(x2)\displaystyle y-1=-4(x-2) Distribute 4-4: y1=4x+8\displaystyle y-1=-4x+8 Add 11 to both sides: y=4x+9\displaystyle y=-4x+9 The equation has the same meaning whichever form it is in, and produces the same graph.
image Line graph: Graph of the line y1=4(x2)y-1=-4(x-2), through the point (2,1)(2,1) with slope of 4-4, as well as the slope-intercept form, y=4x+9y=-4x+9.

Example: Write the equation of a line in point-slope form, given point (3,6)(-3,6) and point (1,2)(1,2), and convert to slope-intercept form

Since we have two points, but no slope, we must first find the slope: m=y2y1x2x1\displaystyle m=\frac{y_{2}-y_{1}}{x_{2}-x_{1}} Substituting the values of the points: \displaystyle \begin{align} m&=\frac{-2-6}{1-(-3)}\\&=\frac{-8}{4}\\&=-2 \end{align} Now choose either of the two points, such as (3,6)(-3,6). Plug this point and the calculated slope into the point-slope equation to get: y6=2[x(3)]\displaystyle y-6=-2[x-(-3)] Be careful if one of the coordinates is a negative.  Distributing the negative sign through the parentheses, the final equation is: y6=2(x+3)\displaystyle y-6=-2(x+3) If you chose the other point, the equation would be: y+2=2(x1)y+2=-2(x-1) and either answer is correct. Next distribute 2-2: y6=2x6\displaystyle y-6=-2x-6 Add 66 to both sides: y=2x\displaystyle y=-2x Again, the two forms of the equations are equivalent to each other and produce the same line.  The only difference is the form that they are written in.

Linear Equations in Standard Form

A linear equation written in standard form makes it easy to calculate the zero, or xx-intercept, of the equation.

Learning Objectives

Explain the process and usefulness of converting linear equations to standard form

Key Takeaways

Key Points

  • The standard form of a linear equation is written as: Ax+By=CAx + By = C .
  • The standard form is useful in calculating the zero of an equation. For a linear equation in standard form, if AA is nonzero, then the xx-intercept occurs at x=CAx = \frac{C}{A}.

Key Terms

  • zero: Also known as a root, a zero is an xx-value at which the function of xx is equal to 0.
  • slope-intercept form: A linear equation written in the form y=mx+by = mx + b.
  • y-intercept: A point at which a line crosses the y-axis of a Cartesian grid.

Standard Form

Standard form is another way of arranging a linear equation. In the standard form, a linear equation is written as: Ax+By=C\displaystyle Ax + By = C where AA and BB are both not equal to zero. The equation is usually written so that A0A \geq 0, by convention. The graph of the equation is a straight line, and every straight line can be represented by an equation in the standard form. For example, consider an equation in slope -intercept form: y=12x+5y = -12x +5. In order to write this in standard form, note that we must move the term containing xx to the left side of the equation. We add 12x12x to both sides: y+12x=5\displaystyle y + 12x = 5 The equation is now in standard form.

Using Standard Form to Find Zeroes

Recall that a zero is a point at which a function 's value will be equal to zero (y=0y=0), and is the xx-intercept of the function. We know that the y-intercept of a linear equation can easily be found by putting the equation in slope-intercept form. However, the zero of the equation is not immediately obvious when the linear equation is in this form. However, the zero, or xx-intercept of a linear equation can easily be found by putting it into standard form. For a linear equation in standard form, if AA is nonzero, then the xx-intercept occurs at x=CAx = \frac{C}{A}. For example, consider the equation y+12x=5y + 12x = 5. In this equation, the value of AA is 1, and the value of CC is 5. Therefore, the zero of the equation occurs at x=51=5x = \frac{5}{1} = 5. The zero is the point (5,0)(5, 0). Note that the yy-intercept and slope can also be calculated using the coefficients and constant of the standard form equation. If BB is non-zero, then the y-intercept, that is the y-coordinate of the point where the graph crosses the y-axis (where xx is zero), is CB\frac{C}{B}, and the slope of the line is AB-\frac{A}{B}.

Example: Find the zero of the equation 3(y2)=14x+33(y - 2) = \frac{1}{4}x +3

We must write the equation in standard form, Ax+By=CAx + By = C, which means getting the xx and yy terms on the left side, and the constants on the right side of the equation. Distribute the 3 on the left side: 3y6=14x+3\displaystyle 3y - 6 = \frac{1}{4}x +3 Add 6 to both sides: 3y=14x+9\displaystyle 3y = \frac{1}{4}x + 9 Subtract 14x\frac{1}{4}x from both sides: 3y14x=9\displaystyle 3y - \frac{1}{4}x = 9 Rearrange to Ax+By=CAx + By = C: 14x+3y=9\displaystyle - \frac{1}{4}x+3y = 9 The equation is in standard form, and we can substitute the values for AA and CC into the formula for the zero: \displaystyle \begin{align} x &= \frac{C}{A} \\&= \frac{9}{-\frac{1}{4}} \\&= -36 \end{align} The zero is (36,0)(-36, 0).

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