Implementing Factoring Techniques
When you factor an algebraic expression, you rewrite the sums and differences of the terms as a product. For instance, you write the three terms x2 – x – 42 in factored form as (x – 7)(x + 6). The expression changes from three terms to one big, multiplied-together term. You can factor two terms, three terms, four terms, and so on for many different purposes. The factorization comes in handy when you set the factored forms equal to zero to solve an equation. Factored numerators and denominators in fractions also make it possible to reduce the fractions.
You can think of factoring as the opposite of distributing. You have good reasons to distribute or multiply through by a value – the process allows you to combine like terms and simplify expressions. Factoring out a common factor also has its purposes for solving equations and combining fractions. The different formats are equivalent – they just have different uses.
To factor the expression 6x4 – 6x, for example, you first factor out the common factor, 6x, and then you use the pattern for the difference of two perfect cubes:
Keeping in mind my tip to start a problem off by looking for the greatest common factor, look at the example expression 48x3y2 – 300x3. When you factor the expression, you first divide out the common factor, 12x3, to get 12x3(4y2 – 25). You then factor the difference of perfect squares in the parentheses: 12x3(4y2 – 25) = 12x3(2y – 5)(2y + 5).
Here’s one more: The expression z4 – 81 is the difference of two perfect squares. When you factor it, you get z4 – 81 = (z2 – 9)(z2 + 9). Notice that the first factor is also the difference of two squares – you can factor again. The second term, however, is the sum of squares – you can’t factor it. With perfect cubes, you can factor both differences and sums, but not with the squares. So, the factorization of z4 – 81 is (z – 3)(z + 3)(z2 + 9).
You can often spot the greatest common factor with ease; you see a multiple of some number or variable in each term. With the product of two binomials, you either find the product or become satisfied that it doesn’t exist.
For example, you can perform the factorization of 6x3 – 15x2y + 24xy2 by dividing each term by the common factor, 3x: 6x3 – 15x2y + 24xy2 = 3x(2x2 – 5xy + 8y2).
Trinomials that factor into the product of two binomials have related powers on the variables in two of the terms. The relationship between the powers is that one is twice the other. When factoring a trinomial into the product of two binomials, you first look to see if you have a special product: a perfect square trinomial. If you don’t, you can proceed to unFOIL. The acronym FOIL helps you multiply two binomials (First, Outer, Inner, Last); unFOIL helps you factor the product of those binomials.
Finding perfect square trinomials
To factor x2 – 20x + 100, for example, you should first recognize that 20x is twice the product of the root of x2 and the root of 100; therefore, the factorization is (x – 10)2. An expression that isn’t quite as obvious is 25y2 + 30y + 9. You can see that the first and last terms are perfect squares. The root of 25y2 is 5y, and the root of 9 is 3. The middle term, 30y, is twice the product of 5y and 3, so you have a perfect square trinomial that factors into (5y + 3)2.
Resorting to unFOIL
When you factor a trinomial that results from multiplying two binomials, you have to play detective and piece together the parts of the puzzle. Look at the following generalized product of binomials and the pattern that appears:
So, where does FOIL come in? You need to FOIL before you can unFOIL, don’t ya think?
The F in FOIL stands for “First.” In the previous problem, the First terms are the ax and cx. You multiply these terms together to get acx2. The Outer terms are ax and d. Yes, you already used the ax, but each of the terms will have two different names. The Inner terms are b and cx; the Outer and Inner products are, respectively, adx and bcx. You add these two values. (Don’t worry; when you’re working with numbers, they combine nicely.) The Last terms, b and d, have a product of bd. Here’s an actual example that uses FOIL to multiply – working with numbers for the coefficients rather than letters:
Now, think of every quadratic trinomial as being of the form acx2 + (ad + bc)x + bd. The coefficient of the x2 term, ac, is the product of the coefficients of the two x terms in the parentheses; the last term, bd, is the product of the two second terms in the parentheses; and the coefficient of the middle term is the sum of the outer and inner products. To factor these trinomials into the product of two binomials, you can use the opposite of the FOIL, which I call unFOIL.