13.6 Binomial theorem

Algebra and trigonometry Page 1 / 6

In this section, you will:

Apply the Binomial Theorem.

A polynomial with two terms is called a binomial. We have already learned to multiply binomials and to raise binomials to powers, but raising a binomial to a high power can be tedious and time-consuming. In this section, we will discuss a shortcut that will allow us to find ${(x + y)}^{n}$ without multiplying the binomial by itself $n$ times.

Identifying binomial coefficients

In Counting Principles , we studied combinations . In the shortcut to finding ${(x + y)}^{n},$ we will need to use combinations to find the coefficients that will appear in the expansion of the binomial. In this case, we use the notation $(\begin{matrix} n \\ r \end{matrix})$ instead of $C (n, r),$ but it can be calculated in the same way. So

(\begin{matrix} n \\ r \end{matrix}) = C (n, r) = \frac{n!}{r! (n - r)!}

The combination $(\begin{matrix} n \\ r \end{matrix})$ is called a binomial coefficient . An example of a binomial coefficient is $(\begin{matrix} 5 \\ 2 \end{matrix}) = C (5, 2) = 10.$

A General Note

Binomial coefficients

If $n$ and $r$ are integers greater than or equal to 0 with $n \geq r,$ then the binomial coefficient is

(\begin{matrix} n \\ r \end{matrix}) = C (n, r) = \frac{n!}{r! (n - r)!}

Q&A

Is a binomial coefficient always a whole number?

Yes. Just as the number of combinations must always be a whole number, a binomial coefficient will always be a whole number.

Finding binomial coefficients

Find each binomial coefficient.

$(\begin{matrix} 5 \\ 3 \end{matrix})$
$(\begin{matrix} 9 \\ 2 \end{matrix})$
$(\begin{matrix} 9 \\ 7 \end{matrix})$

Use the formula to calculate each binomial coefficient. You can also use the $n C_{r}$ function on your calculator.

(\begin{matrix} n \\ r \end{matrix}) = C (n, r) = \frac{n!}{r! (n - r)!}

$(\begin{matrix} 5 \\ 3 \end{matrix}) = \frac{5!}{3! (5 - 3)!} = \frac{5 \cdot 4 \cdot 3!}{3! 2!} = 10$
$(\begin{matrix} 9 \\ 2 \end{matrix}) = \frac{9!}{2! (9 - 2)!} = \frac{9 \cdot 8 \cdot 7!}{2! 7!} = 36$
$(\begin{matrix} 9 \\ 7 \end{matrix}) = \frac{9!}{7! (9 - 7)!} = \frac{9 \cdot 8 \cdot 7!}{7! 2!} = 36$

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Try It

Find each binomial coefficient.

$(\begin{matrix} 7 \\ 3 \end{matrix})$
$(\begin{matrix} 11 \\ 4 \end{matrix})$

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Using the binomial theorem

When we expand ${(x + y)}^{n}$ by multiplying, the result is called a binomial expansion , and it includes binomial coefficients. If we wanted to expand ${(x + y)}^{52},$ we might multiply $(x + y)$ by itself fifty-two times. This could take hours! If we examine some simple binomial expansions, we can find patterns that will lead us to a shortcut for finding more complicated binomial expansions.

\begin{array}{l} {(x + y)}^{2} = x^{2} + 2 x y + y^{2} \\ {(x + y)}^{3} = x^{3} + 3 x^{2} y + 3 x y^{2} + y^{3} \\ {(x + y)}^{4} = x^{4} + 4 x^{3} y + 6 x^{2} y^{2} + 4 x y^{3} + y^{4} \end{array}

First, let’s examine the exponents. With each successive term, the exponent for $x$ decreases and the exponent for $y$ increases. The sum of the two exponents is $n$ for each term.

Next, let’s examine the coefficients. Notice that the coefficients increase and then decrease in a symmetrical pattern. The coefficients follow a pattern:

(\begin{matrix} n \\ 0 \end{matrix}), (\begin{matrix} n \\ 1 \end{matrix}), (\begin{matrix} n \\ 2 \end{matrix}), ..., (\begin{matrix} n \\ n \end{matrix}) .

These patterns lead us to the Binomial Theorem , which can be used to expand any binomial.

\begin{array}{l} {(x + y)}^{n} & = \sum_{k = 0}^{n} (\begin{matrix} n \\ k \end{matrix}) x^{n - k} y^{k} \\ = x^{n} + (\begin{matrix} n \\ 1 \end{matrix}) x^{n - 1} y + (\begin{matrix} n \\ 2 \end{matrix}) x^{n - 2} y^{2} + ... + (\begin{matrix} n \\ n - 1 \end{matrix}) x y^{n - 1} + y^{n} \end{array}

Another way to see the coefficients is to examine the expansion of a binomial in general form, $x + y,$ to successive powers 1, 2, 3, and 4.

\begin{array}{l} {(x + y)}^{1} = x + y \\ {(x + y)}^{2} = x^{2} + 2 x y + y^{2} \\ {(x + y)}^{3} = x^{3} + 3 x^{2} y + 3 x y^{2} + y^{3} \\ {(x + y)}^{4} = x^{4} + 4 x^{3} y + 6 x^{2} y^{2} + 4 x y^{3} + y^{4} \end{array}

Can you guess the next expansion for the binomial ${(x + y)}^{5} ?$

See [link] , which illustrates the following:

There are $n + 1$ terms in the expansion of ${(x + y)}^{n} .$
The degree (or sum of the exponents) for each term is $n .$
The powers on $x$ begin with $n$ and decrease to 0.
The powers on $y$ begin with 0 and increase to $n .$
The coefficients are symmetric.

To determine the expansion on ${(x + y)}^{5},$ we see $n = 5,$ thus, there will be 5+1 = 6 terms. Each term has a combined degree of 5. In descending order for powers of $x,$ the pattern is as follows:

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Source: OpenStax, Algebra and trigonometry. OpenStax CNX. Nov 14, 2016 Download for free at https://legacy.cnx.org/content/col11758/1.6

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