reallyguy2

You are asked to expand (x + 7)10.

You will need to multiply (x + 7) times itself 10 times.

(x + 7) (x + 7) (x + 7) (x + 7) (x + 7) (x + 7)(x + 7) (x + 7) (x + 7) (x + 7)

This could take forever - well, at least quite a while!

Is there an easier way to arrive at this expansion?
Let's investigate!

divider
When the binomial expression (a + b)n is expanded, there are certain patterns that are noticeable.
Take a look at the expansions when the values of n range from 0 to 4.
expanded2
If you "pull off" the coefficients of the terms (shown in red), you will discover that the coefficients form a triangle known as
Pascal's Triangle.

Pascal's Triangle can be generated by following a certain pattern.pascaltriangle2
Pascal's Triangle Pattern: The two outside edges of the triangle are comprised of ones.
The other terms are each the sum of the two terms immediately above them in the triangle.
Notice the symmetry of the triangle.
The triangle can grow for as many rows as you desire,
but the work becomes more tedious as the rows increase.

divider

In addition to the observation that the coefficients of a binomial expansion
are the entries that create Pascal's triangle, there are
several other interesting patterns
and observations regarding the expansion of (a + b)n.

1.
The expansion is a series (an adding of the terms, a summation).
2.
The number of terms in each expansion is one more than n. (terms = n + 1)
3.
The power of a starts with an and decreases by one in each successive term ending with a0.
The
power of b starts with b0 and increases by one in each successive term ending with bn.
4.
The power of b is always one less than the "number" of the term.
The
power of a is always n minus the power of b.
5.
The sum of the exponents in each term adds up to n.
6.
The coefficients of the first and last terms are each one.
7.
The coefficients of the middle terms form an interesting (but not easily recognizable) pattern where each coefficient can be determined from the previous term. The coefficient is the product of the previous term's coefficient and a's index (power), divided by the "number" of that previous term.
            Check it out:  bin1

The second term's coefficient is determined by a4:  bin2
To Get Coefficient
From the Previous Term:
bin4
The third term's coefficient is determined by 4a3b: bin3
This pattern will eventually be expressed as a combination of the form n C k.

When these patterns and observations are pulled together, along with some mathematical
syntax, a theorem is formed pertaining to the expansion of binomial terms:

Binomial Theorem
(or Binomial Expansion Theorem)
bin5
Most of the syntax used in this theorem should look familiar. The bin6notation is another way of writing a combination such as n C k (read "n choose k").
bin7

Remember in observation #6 (above) we said there will be a connection between
bin4 and n C k .
Here is the connection: Using our coefficient pattern from #6 in a general setting, we get:bin8
Let's examine the coefficient of that fourth term, the one in the box above.
If we write a combination n C k using k = 3, (for the previous term), we see the connection:
bin9

The Binomial Theorem in expanded form is:bin10 Remember that bin7 and that bin11

divider


pin1
Expand: (x + 2)5
Let a = x, b = 2, n = 5 and substitute into the Binomial Theorem.
Do not substitute a value for k.
bine1
bine12
This is a good time to put your graphing calculator to work to calculate the combinations.
See calculator link at the bottom of this page.
bine13

dividerdash

pin2
Expand: (2x4 - y)3
beware
The "a" value in this problem is the expression "2x4".
Also, the sign is negative making the "b" value "-y".

((2x4) + (-y))3
Let a = (2x4), b = (-y), n = 3 and substitute.
bine2
bine22
Be sure to raise the entire parentheses to the indicated power. Watch out for signs.
Use your calculator for the combinations (see calculator link at bottom of page).
bine23

dividerdash


Finding a Particular Term in a Binomial Expansion

What if you are asked to find just "one" term in a binomial expansion,
such as just the 5th term of (3x - 4)12 ?

Let's call the term we are looking for the rth term. From our observations, we know that the coefficient of this term will be n C r-1, the power of b will be r - 1 and the power of a will be n minus the power of b. Putting this information together gives us a formula for finding the rth term of a binomial expansion.

The rth term of the expansion of (a + b)n is:bineach


pin3
Find 5th term of (3x - 4)12
Let r = 5, a = (3x), b = (-4), n = 12 and substitute.

Use your calculator for the combination.

Be sure to use the parentheses!!

Be careful to raise the entire parentheses to the indicated power.

bine3

ti84c
Check out how to use your graphing calculator with the binomial theorem. Click here.

divider

NOTE: The re-posting of materials (in part or whole) from this site to the Internet is copyright violation
and is not considered "fair use" for educators. Please read the "Terms of Use".