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  • I just did several videos on the binomial theorem, so I

  • think, now that they're done, I think now is good time to do

  • the proof of the derivative of the general form.

  • Let's take the derivative of x to the n.

  • Now that we know the binomial theorem, we

  • have the tools to do it.

  • How do we take the derivative?

  • Well, what's the classic definition of the derivative?

  • It is the limit as delta x approaches zero of f of

  • x plus delta x, right?

  • So f of x plus delta x in this situation is x plus delta

  • x to the nth power, right?

  • Minus f of x, well f of x here is just x to the n.

  • All of that over delta x.

  • Now that we know the binomial theorem we can figure out

  • what the expansion of x plus delta x is to the nth power.

  • And if you don't know the binomial theorem, go to my

  • pre-calculus play list and watch the videos on

  • the binomial theorem.

  • The binomial theorem tells us that this is equal to-- I'm

  • going to need some space for this one-- the limit as

  • delta x approaches zero.

  • And what's the binomial theorem?

  • This is going to be equal to-- I'm just going to do the

  • numerator-- x to the n plus n choose 1.

  • Once again, review the binomial theorem if this is looks like

  • latin to you and you don't know latin.

  • n choose 1 of x to the n minus 1 delta x plus n choose 2 x to

  • the n minus 2, that's x n minus 2, delta x squared.

  • Then plus, and we have a bunch of the digits, and in this

  • proof we don't have to go through all the digits but the

  • binomial theorem tells us what they are and, of course, the

  • last digit we just keep adding is going to be 1-- it would

  • be n choose n which is 1.

  • Let me just write that down. n choose n.

  • It's going to be x to the zero times delta x to the n.

  • So that's the binomial expansion.

  • Let me switch back to minus, green that's x plus delta x

  • to the n, so minus x to the n power.

  • That's x to the n, I know I squashed it there.

  • All of that over delta x.

  • Let's see if we can simplify.

  • First of all we have an x to the n here, and at the very end

  • we subtract out an x to the n, so these two cancel out.

  • If we look at every term here, every term in the numerator has

  • a delta x, so we can divide the numerator and the

  • denominator by delta x.

  • This is the same thing as 1 over delta x times

  • this whole thing.

  • So that is equal to the limit as delta x approaches zero of,

  • so we divide the top and the bottom by delta x, or we

  • multiply the numerator times 1 over delta x.

  • We get n choose 1 x to the n minus 1.

  • What's delta x divided by delta x, that's just 1.

  • Plus n choose 2, x to the n minus 2.

  • This is delta x squared, but we divide by delta x we

  • just get a delta x here.

  • Delta x.

  • And then we keep having a bunch of terms, we're going to divide

  • all of them by delta x.

  • And then the last term is delta x to the n, but then

  • we're going to divide that by delta x.

  • So the last term becomes n choose n, x to the zero is 1,

  • we can ignore that. delta x to the n divided by delta x.

  • Well that's delta x to the n minus 1.

  • Then what are we doing now?

  • Remember, we're taking the limit as delta

  • x approaches zero.

  • As delta x approaches zero, pretty much every term that

  • has a delta x in it, it becomes zero.

  • When you multiply but zero, you get zero.

  • This first term has no delta x in it, but

  • every other term does.

  • Every other term, even after we divided by delta x

  • has a delta x in it.

  • So that's a zero.

  • Every term is zero, all of the other n minus 1

  • terms, they're all zeros.

  • All we're left with is that this is equal to n choose

  • 1 of x the n minus 1.

  • And what's n choose 1?

  • That equals n factorial over 1 factorial divided by n minus 1

  • factorial times x to the n minus 1.

  • 1 factorial is 1.

  • If I have 7 factorial divided by 6 factorial, that's just 1.

  • Or if I have 3 factorial divided by 2 factorial, that's

  • just 3, you can work it out.

  • 10 factorial divided by 9 factorial that's 10.

  • So n factorial divided by n minus 1 factorial,

  • that's just equal to n.

  • So this is equal to n times x to the n minus 1.

  • That's the derivative of x to the n. n times

  • x to the n minus 1.

  • We just proved the derivative for any positive integer when

  • x to the power n, where n is any positive integer.

  • And we see later it actually works for all real

  • numbers and the exponent.

  • I will see you in a future video.

  • Another thing I wanted to point out is, you know I said that

  • we had to know the binomial theorem.

  • But if you think about it, we really didn't even have to know

  • the binomial theorem because we knew in any binomial

  • expansion-- I mean, you'd have to know a little bit-- but if

  • you did a little experimentation you would

  • realize that whenever you expand a plus b to the nth

  • power, first term is going to be a to the n, and the second

  • term is going to be plus n a to the n minus 1 b.

  • And then you are going to keep having a bunch of terms.

  • But these are the only terms that are relevant to this proof

  • because all the other terms get canceled out when delta

  • x approaches zero.

  • So if you just knew that you could have done this, but it's

  • much better to do it with the binomial theorem.

  • Ignore what I just said if it confused you.

  • I'm just saying that we could have just said the rest of

  • these terms all go to zero.

  • Anyway, hopefully you found that fulfilling.

  • I will see you in future videos.

I just did several videos on the binomial theorem, so I

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