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# Special Products of Polynomials

## Work with multiple variables with special products of polynomials. Learn how to solve binomial squares, and the difference of squares with binomials.

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Special Products of Polynomials

What if you wanted to multiply two binomials that were exactly the same, like ? Similarly what if you wanted to multiply two binomials in which the sign between the two terms was the opposite in one from the other, like ? What shortcuts could you use? After completing this Concept, you'll be able to find the square of a binomial as well as the product of binomials using the sum and difference formula.

### Guidance

We saw that when we multiply two binomials we need to make sure to multiply each term in the first binomial with each term in the second binomial. Let’s look at another example.

Multiply two linear binomials (binomials whose degree is 1):

When we multiply, we obtain a quadratic polynomial (one with degree 2) with four terms:

The middle terms are like terms and we can combine them. We simplify and get . This is a quadratic, or second-degree, trinomial (polynomial with three terms).

You can see that every time we multiply two linear binomials with one variable, we will obtain a quadratic polynomial. In this section we’ll talk about some special products of binomials.

Find the Square of a Binomial

One special binomial product is the square of a binomial. Consider the product .

Since we are multiplying the same expression by itself, that means we are squaring the expression. is the same as .

When we multiply it out, we get , which simplifies to .

Notice that the two middle terms—the ones we added together to get —were the same. Is this a coincidence? In order to find that out, let’s square a general linear binomial.

Sure enough, the middle terms are the same. How about if the expression we square is a difference instead of a sum?

It looks like the middle two terms are the same in general whenever we square a binomial. The general pattern is: to square a binomial, take the square of the first term, add or subtract twice the product of the terms, and add the square of the second term. You should remember these formulas:

Remember! Raising a polynomial to a power means that we multiply the polynomial by itself however many times the exponent indicates. For instance, . Don’t make the common mistake of thinking that ! To see why that’s not true, try substituting numbers for and into the equation (for example, and ), and you will see that it is not a true statement. The middle term, , is needed to make the equation work.

We can apply the formulas for squaring binomials to any number of problems.

#### Example A

Square each binomial and simplify.

a)

b)

c)

Solution

Let’s use the square of a binomial formula to multiply each expression.

a)

If we let and , then our formula becomes , which simplifies to .

b)

If we let and , then our formula becomes , which simplifies to .

c)

If we let and , then

Find the Product of Binomials Using Sum and Difference Patterns

Another special binomial product is the product of a sum and a difference of terms. For example, let’s multiply the following binomials.

Notice that the middle terms are opposites of each other, so they cancel out when we collect like terms. This is not a coincidence. This always happens when we multiply a sum and difference of the same terms. In general,

When multiplying a sum and difference of the same two terms, the middle terms cancel out. We get the square of the first term minus the square of the second term. You should remember this formula.

Sum and Difference Formula:

Let’s apply this formula to a few examples.

#### Example B

Multiply the following binomials and simplify.

a)

b)

c)

Solution

a) Let and , then:

b) Let and , then:

c) Let and , then:

Solve Real-World Problems Using Special Products of Polynomials

Now let’s see how special products of polynomials apply to geometry problems and to mental arithmetic.

#### Example C

Find the area of the following square:

Solution

The length of each side is , so the area is .

Notice that this gives a visual explanation of the square of a binomial. The blue square has area , the red square has area , and each rectangle has area , so added all together, the area is equal to .

The next example shows how you can use the special products to do fast mental calculations.

#### Example D

Use the difference of squares and the binomial square formulas to find the products of the following numbers without using a calculator.

a)

b)

c)

Solution

The key to these mental “tricks” is to rewrite each number as a sum or difference of numbers you know how to square easily.

a) Rewrite 43 as and 57 as .

Then

b)

c) Rewrite 481 as and 319 as .

Then

is easy - it equals 160000.

is not easy to do mentally, so let’s rewrite 81 as .

Then

Watch this video for help with the Examples above.

### Vocabulary

• Square of a binomial: and
• Sum and difference formula:

### Guided Practice

1. Square the binomial and simplify: .

2. Multiply and simplify.

3. Use the difference of squares and the binomial square formulas to find the product of without using a calculator.

Solutions:

1.)

If we let and , then

2.) Let and , then:

3. ) The key to these mental “tricks” is to rewrite each number as a sum or difference of numbers you know how to square easily.

Rewrite 112 as and 88 as .

Then

### Practice

Use the special product rule for squaring binomials to multiply these expressions.

Use the special product of a sum and difference to multiply these expressions.

Find the area of the lower right square in the following figure.

Multiply the following numbers using special products.

### Vocabulary Language: English

Binomial

Binomial

A binomial is an expression with two terms. The prefix 'bi' means 'two'.
Square of a Binomial

Square of a Binomial

The product of a squared binomial is always a trinomial.