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  • What I want to do in this video is give you

  • a bunch of properties of limits.

  • And we're not going to prove it rigorously here.

  • In order to have the rigorous proof of these properties,

  • we need a rigorous definition of what a limit is.

  • And we're not doing that in this tutorial,

  • we'll do that in the tutorial on the epsilon delta

  • definition of limits.

  • But most of these should be fairly intuitive.

  • And they are very helpful for simplifying limit problems

  • in the future.

  • So let's say we know that the limit of some function

  • f of x, as x approaches c, is equal to capital L.

  • And let's say that we also know that the limit

  • of some other function, let's say g of x, as x approaches c,

  • is equal to capital M.

  • Now given that, what would be the limit of f

  • of x plus g of x as x approaches c?

  • Well-- and you could look at this visually,

  • if you look at the graphs of two arbitrary functions,

  • you would essentially just add those two functions--

  • it'll be pretty clear that this is going to be equal to--

  • and once again, I'm not doing a rigorous proof,

  • I'm just really giving you the properties here--

  • this is going to be the limit of f of x as x approaches c,

  • plus the limit of g of x as x approaches c.

  • Which is equal to, well this right over here

  • is-- let me do that in that same color--

  • this right here is just equal to L.

  • It's going to be equal to L plus M. This right over here

  • is equal to M.

  • Not too difficult.

  • This is often called the sum rule, or the sum property,

  • of limits.

  • And we could come up with a very similar one with differences.

  • The limit as x approaches c of f of x minus g of x,

  • is just going to be L minus M. It's just

  • the limit of f of x as x approaches

  • c, minus the limit of g of x as x approaches c.

  • So it's just going to be L minus M.

  • And we also often call it the difference

  • rule, or the difference property, of limits.

  • And these once again, are very, very, hopefully, reasonably

  • intuitive.

  • Now what happens if you take the product of the functions?

  • The limit of f of x times g of x as x approaches c.

  • Well lucky for us, this is going to be

  • equal to the limit of f of x as x approaches

  • c, times the limit of g of x, as x approaches c.

  • Lucky for us, this is kind of a fairly intuitive property

  • of limits.

  • So in this case, this is just going

  • to be equal to, this is L times M. This is just

  • going to be L times M. Same thing,

  • if instead of having a function here, we had a constant.

  • So if we just had the limit-- let

  • me do it in that same color-- the limit of k times

  • f of x, as x approaches c, where k is just some constant.

  • This is going to be the same thing as k times the limit

  • of f of x as x approaches c.

  • And that is just equal to L. So this whole thing

  • simplifies to k times L.

  • And we can do the same thing with difference.

  • This is often called the constant multiple property.

  • We can do the same thing with differences.

  • So if we have the limit as x approaches

  • c of f of x divided by g of x.

  • This is the exact same thing as the limit

  • of f of x as x approaches c, divided

  • by the limit of g of x as x approaches c.

  • Which is going to be equal to-- I think you get it now--

  • this is going to be equal to L over M.

  • And finally-- this is sometimes called the quotient property--

  • finally we'll look at the exponent property.

  • So if I have the limit of-- let me

  • write it this way-- of f of x to some power.

  • And actually, let me even write it

  • as a fractional power, to the r over s

  • power, where both r and s are integers, then the limit of f

  • of x to the r over s power as x approaches c,

  • is going to be the exact same thing as the limit of f

  • of x as x approaches c raised to the r over s power.

  • Once again, when r and s are both integers, and s

  • is not equal to 0.

  • Otherwise this exponent would not make much sense.

  • And this is the same thing as L to the r over s power.

  • So this is equal to L to the r over s power.

  • So using these, we can actually find

  • the limit of many, many, many things.

  • And what's neat about it is the property of limits kind of

  • are the things that you would naturally want to do.

  • And if you graph some of these functions,

  • it actually turns out to be quite intuitive.

What I want to do in this video is give you

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A2 初級 美國腔

極限的特性(Limit properties | Limits and continuity | AP Calculus AB | Khan Academy)

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    yukang920108 發佈於 2022 年 07 月 01 日
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