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  • In the last video, we tried to come up

  • with a somewhat rigorous definition of what a limit is,

  • where we say when you say that the limit of f

  • of x as x approaches C is equal L, you're really saying--

  • and this is the somewhat rigorous definition--

  • that you can get f of x as close as you

  • want to L by making x sufficiently close to C.

  • So let's see if we can put a little bit of meat on it.

  • So instead of saying as close as you want,

  • let's call that some positive number epsilon.

  • So I'm just going to use the Greek letter epsilon right over

  • there.

  • So it really turns into a game.

  • So this is the game.

  • You tell me how close you want f of x to be to L.

  • And you do this by giving me a positive number that we call

  • epsilon, which is really how close you want

  • f of x to be to L. So you give a positive number epsilon.

  • And epsilon is how close do you want to be?

  • How close?

  • So for example, if epsilon is 0.01,

  • that says that you want f of x to be within 0.01 of epsilon.

  • And so what I then do is I say well, OK.

  • You've given me that epsilon.

  • I'm going to find you another positive number which we'll

  • call delta-- the lowercase delta, the Greek letter

  • delta-- such that where if x is within delta of C,

  • then f of x will be within epsilon of our limit.

  • So let's see if these are really saying the same thing.

  • In this yellow definition right over here,

  • we said you can get f of x as close

  • as you want to L by making x sufficiently close to C.

  • This second definition, which I kind of

  • made as a little bit more of a game, is doing the same thing.

  • Someone is saying how close they want f of x to be to L

  • and the burden is then to find a delta where as long

  • as x is within delta of C, then f of x

  • will be within epsilon of the limit.

  • So that is doing it.

  • It's saying look, if we are constraining x in such a way

  • that if x is in that range to C, then

  • f of x will be as close as you want.

  • So let's make this a little bit clearer

  • by diagramming right over here.

  • You show up and you say well, I want

  • f of x to be within epsilon of our limit.

  • This point right over here is our limit plus epsilon.

  • And this right over here might be our limit minus epsilon.

  • And you say, OK, sure.

  • I think I can get your f of x within this range of our limit.

  • And I can do that by defining a range around C.

  • And I could visually look at this boundary.

  • But I could even go narrower than that boundary.

  • I could go right over here.

  • Says OK, I meet your challenge.

  • I will find another number delta.

  • So this right over here is C plus delta.

  • This right over here is C minus-- let

  • me write this down-- is C minus delta.

  • So I'll find you some delta so that if you

  • take any x in the range C minus delta to C

  • plus delta-- and maybe the function's not even

  • defined at C, so we think of ones

  • that maybe aren't C, but are getting very close.

  • If you find any x in that range, f of those

  • x's are going to be as close as you want to your limit.

  • They're going to be within the range L plus epsilon or L

  • minus epsilon.

  • So what's another way of saying this?

  • Another way of saying this is you give me an epsilon,

  • then I will find you a delta.

  • So let me write this in a little bit more math notation.

  • So I'll write the same exact statements

  • with a little bit more math here.

  • But it's the exact same thing.

  • Let me write it this way.

  • Given an epsilon greater than 0-- so

  • that's kind of the first part of the game--

  • we can find a delta greater than 0, such

  • that if x is within delta of C.

  • So what's another way of saying that x is within delta of C?

  • Well, one way you could say, well,

  • what's the distance between x and C

  • is going to be less than delta.

  • This statement is true for any x that's within delta of C.

  • The difference between the two is going to be less than delta.

  • So that if you pick an x that is in this range between C

  • minus delta and C plus delta, and these

  • are the x's that satisfy that right over here, then--

  • and I'll do this in a new color-- then

  • the distance between your f of x and your limit--

  • and this is just the distance between the f of x

  • and the limit, it's going to be less than epsilon.

  • So all this is saying is, if the limit truly does exist,

  • it truly is L, is if you give me any positive number epsilon,

  • it could be super, super small one, we can find a delta.

  • So we can define a range around C

  • so that if we take any x value that

  • is within delta of C, that's all this statement

  • is saying that the distance between x and C

  • is less than delta.

  • So it's within delta of C. So that's

  • these points right over here.

  • That f of those x's, the function

  • evaluated at those x's is going to be within the range

  • that you are specifying.

  • It's going to be within epsilon of our limit.

  • The f of x, the difference between f of x, and your limit

  • will be less than epsilon.

  • Your f of x is going to sit some place over there.

  • So that's all the epsilon-delta definition is telling us.

  • In the next video, we will prove that a limit exists

  • by using this definition of limits.

In the last video, we tried to come up

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Epsilon-delta definition of limits

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    yukang920108 に公開 2022 年 07 月 05 日
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