Factoring and the Square Root Property

Learning Outcomes

  • Factor a quadratic equation to solve it.
  • Use the square root property to solve a quadratic equation.
  • Use the Pythagorean Theorem and the square root property to find the unknown length of the side of a right triangle.

Recall: identifying polynomials

Recall that a polynomial is an expression containing variable terms joined together by addition or subtraction. We can identify the degree of the polynomial by finding the term having the highest power (largest exponent on its variable). That term will be the leading term of the polynomial and its degree is the degree of the polynomial.

An equation containing a second-degree polynomial is called a quadratic equation. For example, equations such as [latex]2{x}^{2}+3x - 1=0[/latex] and [latex]{x}^{2}-4=0[/latex] are quadratic equations. They are used in countless ways in the fields of engineering, architecture, finance, biological science, and, of course, mathematics.

Often the easiest method of solving a quadratic equation is factoring. Factoring means finding expressions that can be multiplied together to give the expression on one side of the equation.

If a quadratic equation can be factored, it is written as a product of linear terms. Solving by factoring depends on the zero-product property which states that if [latex]a\cdot b=0[/latex], then [latex]a=0[/latex] or [latex]b=0[/latex], where a and b are real numbers or algebraic expressions. In other words, if the product of two numbers or two expressions equals zero, then one of the numbers or one of the expressions must equal zero because zero multiplied by anything equals zero.

Multiplying the factors expands the equation to a string of terms separated by plus or minus signs. So, in that sense, the operation of multiplication undoes the operation of factoring. For example, expand the factored expression [latex]\left(x - 2\right)\left(x+3\right)[/latex] by multiplying the two factors together.

[latex]\begin{array}{l}\left(x - 2\right)\left(x+3\right)\hfill&={x}^{2}+3x - 2x - 6\hfill \\ \hfill&={x}^{2}+x - 6\hfill \end{array}[/latex]

The product is a quadratic expression. Set equal to zero, [latex]{x}^{2}+x - 6=0[/latex] is a quadratic equation. If we were to factor the equation, we would get back the factors we multiplied.

The process of factoring a quadratic equation depends on the leading coefficient, whether it is 1 or another integer. We will look at both situations; but first, we want to confirm that the equation is written in standard form, [latex]a{x}^{2}+bx+c=0[/latex], where a, b, and c are real numbers and [latex]a\ne 0[/latex]. The equation [latex]{x}^{2}+x - 6=0[/latex] is in standard form.

recall the greatest common factor

The greatest common factor (GCF) is the largest number or variable expression that can divided evenly into two or more numbers or expressions.

To find the GCF of an expression containing variable terms, first find the GCF of the coefficients, then find the GCF of the variables. The GCF of the variables will be the smallest degree of each variable that appears in each term.

For example, [latex]4x[/latex] is the GCF of [latex]16x[/latex] and [latex]20{x}^{2}[/latex] because it is the largest expression that divides evenly into both [latex]16x[/latex] and [latex]20{x}^{2}[/latex].

When factoring, remember to look first for a greatest common factor. If you can find one to factor out, it will usually make your factoring task less challenging.

We can use the zero-product property to solve quadratic equations in which we first have to factor out the greatest common factor (GCF), and for equations that have special factoring formulas as well, such as the difference of squares, both of which we will see later in this section.

A General Note: The Zero-Product Property and Quadratic Equations

The zero-product property states

[latex]\text{If }a\cdot b=0,\text{ then }a=0\text{ or }b=0[/latex],

where a and b are real numbers or algebraic expressions.

A quadratic equation is an equation containing a second-degree polynomial; for example

[latex]a{x}^{2}+bx+c=0[/latex]

where a, b, and c are real numbers, and [latex]a\ne 0[/latex]. It is in standard form.

Solving Quadratics with a Leading Coefficient of 1

In the quadratic equation [latex]{x}^{2}+x - 6=0[/latex], the leading coefficient, or the coefficient of [latex]{x}^{2}[/latex], is 1. We have one method of factoring quadratic equations in this form.

How To: Given a quadratic equation with the leading coefficient of 1, factor it

  1. Find two numbers whose product equals c and whose sum equals b.
  2. Use those numbers to write two factors of the form [latex]\left(x+k\right)\text{ or }\left(x-k\right)[/latex], where k is one of the numbers found in step 1. Use the numbers exactly as they are. In other words, if the two numbers are 1 and [latex]-2[/latex], the factors are [latex]\left(x+1\right)\left(x - 2\right)[/latex].
  3. Solve using the zero-product property by setting each factor equal to zero and solving for the variable.

Example: Factoring and Solving a Quadratic with Leading Coefficient of 1

Factor and solve the equation: [latex]{x}^{2}+x - 6=0[/latex].

Try It

Factor and solve the quadratic equation: [latex]{x}^{2}-5x - 6=0[/latex].

Using the Square Root Property

When there is no linear term in the equation, another method of solving a quadratic equation is by using the square root property, in which we isolate the [latex]{x}^{2}[/latex] term and take the square root of the number on the other side of the equal sign. Keep in mind that sometimes we may have to manipulate the equation to isolate the [latex]{x}^{2}[/latex] term so that the square root property can be used.

A General Note: The Square Root Property

With the [latex]{x}^{2}[/latex] term isolated, the square root propty states that:

[latex]\text{if }{x}^{2}=k,\text{then }x=\pm \sqrt{k}[/latex]

where k is a nonzero real number.

Recall: principal square root

Recall that the princicpal square root of a number such as [latex]\sqrt{9}[/latex] is the non-negative root, [latex]3[/latex].

And note that there is a difference between [latex]\sqrt{9}[/latex]  and [latex]{x}^{2}=9[/latex]. In the case of [latex]{x}^{2}=9[/latex], we seek all numbers whose square is 9, that is [latex]x=\pm 3[/latex].

How To: Given a quadratic equation with an [latex]{x}^{2}[/latex] term but no [latex]x[/latex] term, use the square root property to solve it

  1. Isolate the [latex]{x}^{2}[/latex] term on one side of the equal sign.
  2. Take the square root of both sides of the equation, putting a [latex]\pm[/latex] sign before the expression on the side opposite the squared term.
  3. Simplify the numbers on the side with the [latex]\pm[/latex] sign.

Example: Solving a Simple Quadratic Equation Using the Square Root Property

Solve the quadratic using the square root property: [latex]{x}^{2}=8[/latex].

Example: Solving a Quadratic Equation Using the Square Root Property

Solve the quadratic equation: [latex]4{x}^{2}+1=7[/latex]

Try It

Solve the quadratic equation using the square root property: [latex]3{\left(x - 4\right)}^{2}=15[/latex].

Using the Pythagorean Theorem

One of the most famous formulas in mathematics is the Pythagorean Theorem. It is based on a right triangle and states the relationship among the lengths of the sides as [latex]{a}^{2}+{b}^{2}={c}^{2}[/latex], where [latex]a[/latex] and [latex]b[/latex] refer to the legs of a right triangle adjacent to the [latex]90^\circ[/latex] angle, and [latex]c[/latex] refers to the hypotenuse. It has immeasurable uses in architecture, engineering, the sciences, geometry, trigonometry, and algebra, and in everyday applications.

We use the Pythagorean Theorem to solve for the length of one side of a triangle when we have the lengths of the other two. Because each of the terms is squared in the theorem, when we are solving for a side of a triangle, we have a quadratic equation. We can use the methods for solving quadratic equations that we learned in this section to solve for the missing side.

The Pythagorean Theorem is given as

[latex]{a}^{2}+{b}^{2}={c}^{2}[/latex]

where [latex]a[/latex] and [latex]b[/latex] refer to the legs of a right triangle adjacent to the [latex]{90}^{\circ }[/latex] angle, and [latex]c[/latex] refers to the hypotenuse.

Right triangle with the base labeled: a, the height labeled: b, and the hypotenuse labeled: c

Example: Finding the Length of the Missing Side of a Right Triangle

Find the length of the missing side of the right triangle.

Right triangle with the base labeled: a, the height labeled: 4, and the hypotenuse labeled 12.

Try It

Use the Pythagorean Theorem to solve the right triangle problem: Leg a measures 4 units, leg b measures 3 units. Find the length of the hypotenuse.