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## Algebra 1

### Course: Algebra 1 > Unit 13

Lesson 3: Special products of binomials- Special products of the form (x+a)(x-a)
- Squaring binomials of the form (x+a)²
- Multiply difference of squares
- Multiply perfect squares of binomials
- Special products of the form (ax+b)(ax-b)
- Squaring binomials of the form (ax+b)²
- Binomial special products review

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# Squaring binomials of the form (ax+b)²

Sal expands the perfect square (7x+10)² as 49x^2+140x+100. Created by Sal Khan and Monterey Institute for Technology and Education.

## Want to join the conversation?

- I don't get it. How is (7x)^2 + (10)^2 wrong?(28 votes)
- You can see how it is wrong if you think about it with real numbers instead of x.

For example, let x = 1.

Now we have (7+10)^2 which is 17^2=289

It is NOT 7^2 + 10^2 = 49 + 100 = 149

If you do it that way you lose the 2 middle terms, in this case 2(7*10), and as you can see, our answer is off by the amount of those terms, 2*7*10 = 140.(70 votes)

- why is 7x squared+ 10 squared wrong? I don't get it.(5 votes)
- You can see how it is wrong if you think about it with real numbers instead of x.

For example, let x = 1.

Now we have (7+10)^2 which is 17^2=289

It is NOT 7^2 + 10^2 = 49 + 100 = 149

If you do it that way you lose the 2 middle terms, in this case 2(7*10), and as you can see, our answer is off by the amount of those terms, 2*7*10 = 140.(27 votes)

- At0:23isn't pretty redundant to point this out this late in the course wouldn't it help to emphasize this point earlier?(8 votes)
- True. However, perhaps some people might forget.(3 votes)

- Does this apply to numbers as well, lets say (2+8)^2, or is it only when there are variables involved?(4 votes)
- It applies to non-variable expressions as well, but it's pretty pointless to use this method on those, since it's needlessly complicated and slow compared to simplifying the expression the traditional way (using the order of operations). See below:

Using the order of operations:`(2 + 8)^2 = (10)^2 = 100`

Using this "shortcut":`(a + b)^2 = a^2 + 2ab + b^2`

`(2 + 8)^2 = 2^2 + 2(2)(8) + 8^2 = 4 + 32 + 64 = 100`

So that's why this trick is only a shortcut if variables are involved.(5 votes)

- Video3:17

The (a+b)^2 doesn't match up with the the working example of (7x+10)^2? Yes, that's a question. I'm taking calculus online, which is a nightmare and I am probably the worst at math that you will ever meet.

Anyways, my dilemma is I'm trying to understand where the 2(7x)(10) is coming from. In the (a+b)^2 example I can follow as the ab+ab is from the distribution. However, the 2(7x)(10) from what I can tell and the lack of clarity besides "you multiply these by 2" doesn't explain why you do that.

My biggest issue with math is my need to understand something. I excel at physiology and function because I can understand the "why" in something. I am awful at the just do FOIL or use the formula... I'm trying to get better and better at math but I need to know why something is done.(3 votes)- Let's start with (a+b)^2. This creates what is called a perfect square trinomial. It is called a special product because there is a specific pattern that squaring a binomial creates. You have 2 choices for simplifying it. You can multiply (FOIL) the 2 binomials (a+b)(a+b), or you can use the pattern.

When you FOIL: (a+b)(a+b) = a(a) + a(b) + a(b) + b(b) = a^2 + ab + ab + b^2. Notice, the two middle terms are exactly the same. This is always true when a binomial is squared. When you add those 2 terms, you add their coefficients and they create 2ab. Hopefully that helps you see where the 2ab comes from. So, the patter is: (a+b)(a+b) = a^2 + 2ab + b^2.

Now, let's apply the pattern to (7x+10)^2, Sometimes it helps if you identify what is "a" and "b". In this case: a = 7x and b = 10. This helps you to apply the pattern, because you know what to put in for the variables "a" and "b". Here goes...

a^2 = (7x)^2

2ab = 2(7x)(10)

b^2 = 10^2.

Put the pieces together and simplify to get the result: (7x)^2 + 2(7x)(10) + 10^2 = 49x^2 + 140x + 100.

I'm going to use FOIL on the same problem to try to point out how the pattern relates to it.

(7x+10)(7x+10) = (7x)(7x) + 7x(10) + 10(7x) + 10(10) = (7x)^2 + 70x + 70x + 10^2

Again, notice the 2 middle terms match. 70x + 70x = 2(70x) = 140x (same as in the pattern).

Finishing... (7x+10)(7x+10) = 49x^2 +140x + 100.

Hope this helps.(8 votes)

- would this work for (-5wx^5)^3? how would I do it? thanks(3 votes)
- Hi Brittany,

When we have an exponent outside of parenthesis and we are only multiplying or dividing inside the parenthesis, the exponent gets applied to each part of the term. So this gives us:

-5^3 = -125

w^3 = w^3

(x^5)^3 = x^15

Put it all together and we get

-125(w^3)(x^15)

I used parenthesis so that it's easier to read.

Binomials are different because now we have two terms that we are either adding or subtracting. In this case, we have to use FOIL or some similar method. Example:

(2x + y^2)^2

In this case, we have the equivalent of

(2x + y^2)(2x + y^2)

So using FOIL we get

4x^2 + 2xy^2 + 2xy^2 + y^4

Clean it up by combining like terms and we get

4x^2 + 4xy^2 + y^4

Hope this helps your understanding some :-)(4 votes)

- at2:56...(7x)^2 + 2(7x)(10)+ 10^2..I didn't get it...where does the 2(7x)(10) from?I mean can you explain all of it?hehe thank you!(2 votes)
- When you square a binomial, there are 2 ways to do it.

1) You use FOIL or extended distribution. 2) You use the pattern that always occurs when you square a binomial. Sal shows you that pattern when he multiplies (a+b)^2 = (a+b)(a+b) = a^2+ab+ab+b^2

Notice - the 2 middle terms match! They are like terms and combine into a^2+2ab+b^2

If you square any binomial (a+b)^2, your result will be equivalent to a^2+2ab+b^2

Sal applies this pattern when you squares (7x+10)^2.

"a" = 7x

"b" = 10

So, using the pattern...

a^2 = (7x)^2

2ab = 2(7x)(10)

b^2 = 10^2

To better understand the 2(7x)(10), use FOIL. But, I'm going to do it without actually performing the full multiplication.

(7x+10)(7x+10) = 7x(7x) + 7x(10) + 7x(10) + 10(10)

7x(7x) is 7x^2, the same as a^2 using the pattern.

7x(10)+7x(10) = 2(7x)(10), the same as 2ab in the pattern

10(10) = 10^2, the same as in the pattern.

Hope this helps.(5 votes)

- this was in an exercise before this vid no wonder i didn't understand it at first(4 votes)
- Yeah, I got some problems like this before this video as well.(1 vote)

- the way of formatting this method seems more complicated instead of foil and distrubiting im confused is this supposed to be better(1 vote)
- This method is known as double distribution and may be important as you move beyond multiplying binomials. (x+3)(x^2+2x+5) - the idea is to multiply everything in first times the second, so x(x^2+2x+5)+3(x^2+2x+5). FOIL is good, but limited to a binomial times a binomial.(5 votes)

- I feel like something's wrong at0:16/s(0 votes)
- Sal is showing you a common error that students make. He clearly labels it at "WRONG!" at @0:20in the video.(5 votes)

## Video transcript

We're asked to simply, or expand (7x + 10) ^ 2 Now the first thing I will show you is exactly what you should NOT do, well there's this huge temptation. A lot of people will look at this and say oh, that's (7x)^2 + 10^2. This is WRONG. And I'll write it in caps. This is WRONG! What your brain is doing is thinking if I had 7x times 10 and I squared that, this would be (7x)^2 times 10^2. We aren't multiplying here, we're adding 7x to 10. So you can't just square each of these terms. I just wanted to highlight, this is completely wrong, and to see why it's wrong, you have to remind yourself that (7x + 10)^2 is the exact same thing as (7x + 10)(7x + 10). That's what it means to square something. You're multiplying it by itself twice here. So this is what it is, so we're really just multiplying a binomial, or two binomials, they just happen to be the same one, and you could use F.O.I.L., you could use the distributive method, but this is actually a special case: when you're squaring a binomial, so let's just think about it as a special case first then we can apply whatever we learn to this. So we could've just done it straight here, but I want to learn the general case so you can apply it to any problem that you might see. If I have (a+b) squared We already realised that it's not a squared plus b squared That is a plus b times a plus b. and now we can use the distributive property We can distribute this a + b times this a So we get, we get a times a plus b and we can distribute the a plus b times this b plus b times a plus b, and we distribute this a we get a squared plus ab plus b times a is another ab And I'm just swapping the order so it's the same as this. plus b times b which is b squared. These are the same or these are like terms. So we can add them. One of something plus another of that something will give you two of that something. 2 ab. We have a squared plus 2 ab plus b squared. So the pattern here, the pattern here, if I have a plus b squared it's equal to a squared plus 2 times the product of these numbers plus b squared. So over here I have seven x plus ten squared So this is going to be equal to seven x squared seven x squared plus 2 times the product of seven x and 10. 2 times seven x times 10 plus 10 squared. So, the difference between the right answer and the wrong answer is that you have this middle term here that you might have forgotten about if you did it this way. And this comes out when you are multiplying all the different combinations of the terms here. if we simplify this, if we simplify seven x squared That's seven squared times x squared. So seven squared is 49 times x squared When you multiply this part out 2 times 7 times 10 which is 140 and then we have our x. No other x there. And then plus 10 squared. So plus 100. And we are done.