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  • Let's say that f of x is equal to the natural log of x,

  • and we want to figure out what the slope of the tangent line

  • to the curve f is when x is equal to the number e.

  • So here, x is equal to the number e.

  • The point e comma 1 is on the curve.

  • f of e is 1.

  • The natural log of e is 1.

  • And I've drawn the slope of the tangent line,

  • or I've drawn the tangent line.

  • And we need to figure out what the slope of it

  • is, or at least come up with an expression for it.

  • And I'm going to come up with an expression using

  • both the formal definition and the alternate definition.

  • That will allow us to compare them a little bit.

  • So let's think about first the formal definition.

  • So the formal definition wants us

  • to find an expression for the derivative of our function

  • at any x.

  • So let's say that this is some arbitrary x right over here.

  • This would be the point x comma f of x.

  • And let's say that this is-- let's call this x plus h.

  • So this distance right over here is going to be h.

  • This right over here is going to be

  • the point, x plus h f of x plus h.

  • Now, the whole underlying idea of the formal definition

  • of limits is to find the slope of the secant line

  • between these two points, and then

  • take the limit as h approaches 0.

  • As h gets closer and closer, this blue point

  • is going to get closer and closer and closer to x.

  • And this point is going to approach it on the curve.

  • And the secant line is going to become

  • a better and better and better approximation

  • of the tangent line at x.

  • So let's actually do that.

  • So what's the slope of the secant line?

  • Well, it's the change in your vertical axis, which

  • is going to be f of x plus h minus f of x--

  • over the change in your horizontal axis.

  • And that's x plus h minus x.

  • And we see here the difference is just h.

  • Over h.

  • And we're going to take the limit of that

  • as h approaches 0.

  • So in the case when f of x is the natural log of x,

  • this will reduce to the limit as h approaches 0.

  • f of x plus h is the natural log of x

  • plus h minus the natural log of x, all of that over h.

  • So this right over here, for our particular f of x,

  • this is equal to f prime of x.

  • So if we wanted to evaluate this when x is equal to e,

  • then everywhere we see an x we just

  • have to replace it with an e.

  • This is essentially expressing our derivative

  • as a function of x.

  • It's kind of a crazy-looking function of x.

  • You have a limit here and all of that.

  • But every place you see an x, like any function definition,

  • you can replace it now with an e.

  • So we can-- let me just do that.

  • Whoops.

  • I lost my screen.

  • Here we go.

  • So we could write f prime of e is

  • equal to the limit as h approaches 0 of natural log--

  • let me do it in the same color so we

  • can keep track of things-- natural log of e plus h--

  • I'll just leave that blank for now--

  • minus the natural log of e, all of that over h.

  • So just like that.

  • This right over here, if we evaluate this limit--

  • if we're able to and we actually can--

  • if we are able to evaluate this limit,

  • this would give us the slope of the tangent line when

  • x equals e.

  • This is doing the formal definition.

  • Now let's do the alternate definition.

  • The alternate definition-- if you

  • don't want to find a general derivative expressed

  • as a function of x like this and you just

  • want to find the slope at a particular point,

  • the alternate definition kind of just gets straight to the point

  • there.

  • So what they say is hey, look, let's imagine

  • some other x value here.

  • So let's imagine some other x value.

  • This right over here is the point x comma-- well,

  • we could say f of x or we could even say the natural log of x.

  • What is the slope of the secant line between those two points?

  • Well, it's going to be your change in y values.

  • So it's going to be natural log of x minus 1--

  • let me do that red color-- over your change in x values.

  • That's x minus e.

  • So that's the slope of the secant line between those two

  • points.

  • Well, what if you want to get the tangent line?

  • Well, let's just take the limit as x approaches e.

  • As x gets closer and closer and closer,

  • these points are going to get closer and closer and closer,

  • and the secant line is going to better approximate

  • the tangent line.

  • So we're just going to take the limit as x approaches e.

  • So either one of this.

  • This is using the formal definition of a limit.

  • Let me make it clear that that h does not belong part of it.

  • So we could either do it using the formal definition

  • or the alternate definition of the derivative.

Let's say that f of x is equal to the natural log of x,

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Formal and alternate form of the derivative for ln x | Differential Calculus | Khan Academy

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    yukang920108 に公開 2022 年 07 月 12 日
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