Placeholder Image

字幕列表 影片播放

  • We're first exposed to the idea of a slope of a line early on

  • in our algebra careers, but I figure it never hurts

  • to review it a bit.

  • So let me draw some axes.

  • That is my y-axis.

  • Maybe I should call it my f of x-axis.

  • y is equal to f of x.

  • Let me draw my x-axis, just like that, that is my x-axis.

  • And let me draw a line, let me draw a line like this.

  • And what we want to do is remind ourselves, how do we

  • find the slope of that line?

  • And what we do is, we take two points on the line,

  • so let's say we take this point, right here.

  • Let's say that that is the point x is equal to a.

  • And then what would this be?

  • This would be the point f of a, where the function is

  • going to be some line.

  • We could write f of x is going to be equal to mx plus b.

  • We don't know what m and b are, but this is all

  • a little bit of review.

  • So this is a.

  • And then the y-value is what happens to the function when

  • you evaluated it at a, so that's that point right there.

  • And then we could take another point on this line.

  • Let's say we take point b, right there.

  • And then this coordinate up here is going to be

  • the point b, f of b.

  • Right?

  • Because this is just the point when you evaluate

  • the function at b.

  • You put b in here, you're going to get that point right there.

  • So let me just draw a little line right there.

  • So that is f of b, right there.

  • Actually, let me make it clear that this coordinate right

  • is the point a, f of a.

  • So how do we find the slope between these 2 points, or more

  • generally, of this entire line?

  • Because whole the slope is consistent the

  • whole way through it.

  • And we know that once we find the slope, that's

  • actually going to be the value of this m.

  • That's all a review of your algebra, but how do we do it?

  • Well, a couple of ways to think about it.

  • Slope is equal to rise over run.

  • You might have seen that when you first learned algebra.

  • Or another way of writing it, it's change in

  • y over change in x.

  • So let's figure out what the change in why over the change

  • in x is for this particular case.

  • So the change in y is equal to what?

  • Well, let's just take, you can take this guy as being the

  • first point, or that guy as being the first point.

  • But since this guy has a larger x and a larger y,

  • let's start with him.

  • The change in y between that guy and that guy is this

  • distance, right here.

  • So let me draw a little triangle.

  • That distance right there is a change in y.

  • Or I could just transfer it to the y-axis.

  • This is the change in y.

  • That is your change in y, that distance.

  • So what is that distance?

  • It's f of b minus f of a.

  • So it equals f of b minus f of a.

  • That is your change in y.

  • Now what is your change in x The slope is change

  • in y over change in x.

  • So what our change in x?

  • What's this distance?

  • Remember, we're taking this to be the first point,

  • so we took its y minus the other point's y.

  • So to be consistent, we're going to have to take this

  • point x minus this point x.

  • So this point's x-coordinate is b.

  • So it's going to be b minus a.

  • And just like that, if you knew the equation of this line, or

  • if you had the coordinates of these 2 points, you would just

  • plug them in right here and you would get your slope.

  • That straightforward.

  • And that comes straight out of your Algebra 1 class.

  • And let me just, just to make sure it's concrete for you, if

  • this was the point 2, 3, and let's say that this, up here,

  • was the point 5, 7, then if we wanted to find the slope of

  • this line, we would do 7 minus 3, that would be our change in

  • y, this would be 7 and this would be 3, and then we

  • do that over 5 minus 2.

  • Because this would be a 5, and this would be a 2, and so this

  • would be your change in x.

  • 5 minus 2.

  • So 7 minus 3 is 4, and 5 minus 2 is 3. so your

  • slope would be 4/3.

  • Now let's see if we can generalize this.

  • And this is what the new concept that we're going

  • to be learning as we delve into calculus.

  • Let's see if we can generalize this somehow to a curve.

  • So let's say I have a curve.

  • We have to have a curve before we can generalize

  • it to a curve.

  • Let me scroll down a little.

  • Well, actually, I want to leave this up here, show

  • you the similarity.

  • Let's say I have, I'll keep it pretty general right now.

  • Let's say I have a curve.

  • I'll make it a familiar-looking curve.

  • Let's say it's the curve y is equal to x squared, which

  • looks something like that.

  • And I want to find the slope.

  • Let's say I want to find the slope at some point.

  • And actually, before even talking about it, let's even

  • think about what it means to find the slope of a curve.

  • Here, the slope was the same the whole time, right?

  • But on a curve your slope is changing.

  • And just to get an intuition for that means, is, what's

  • the slope over here?

  • Your slope over here is the slope of the tangent line.

  • The line just barely touches it.

  • That's the slope over there.

  • It's a negative slope.

  • Then over here, your slope is still negative, but it's a

  • little bit less negative.

  • It goes like that.

  • I don't know if I did that, drew that.

  • Let me do it in a different color.

  • Let me do it in purple.

  • So over here, your slope is slightly less negative.

  • It's a slightly less downward-sloping line.

  • And then when you go over here, at the 0 point, right here,

  • your slope is pretty much flat, because the horizontal line, y

  • equals 0, is tangent to this curve.

  • And then as you go to more positive x's, then your

  • slope starts increasing.

  • I'm trying to draw a tangent line.

  • And here it's increasing even more, it's increased even more.

  • So your slope is changing the entire time, and this is kind

  • of the big change that happens when you go from a

  • line to a curve.

  • A line, your slope is the same the entire time.

  • You could take any two points of a line, take the change in y

  • over the change in x, and you get the slope for

  • the entire line.

  • But as you can see already, it's going to be a little

  • bit more nuanced when we do it for a curve.

  • Because it depends what point we're talking about.

  • We can't just say, what is the slope for this curve?

  • The slope is different at every point along the curve.

  • It changes.

  • If we go up here, it's going to be even steeper.

  • It's going to look something like that.

  • So let's try a bit of an experiment.

  • And I know how this experiment turns out, so it won't

  • be too much of a risk.

  • Let me draw better than that.

  • So that is my y-axis, and that's my x-axis.

  • Let's call this, we can call this y, or we can call

  • this the f of x axis.

  • Either way.

  • And let me draw my curve again.

  • And I'll just draw it in the positive coordinate, like that.

  • That's my curve.

  • And what if I want to find the slope right there?

  • What can I do?

  • Well, based on our definition of a slope, we need 2 points

  • to find a slope, right?

  • Here, I don't know how to find the slope with 1 point.

  • So let's just call this point right here,

  • that's going to be x.

  • We're going to be general.

  • This is going to be our point x.

  • But to find our slope, according to our traditional

  • algebra 1 definition of a slope, we need 2 points.

  • So let's get another point in here.

  • Let's just take a slightly larger version of this x.

  • So let's say, we want to take, actually, let's do it even

  • further out, just because it's going to get messy otherwise.

  • So let's say we have this point right here.

  • And the difference, it's just h bigger than x.

  • Or actually, instead of saying h bigger, let's just, well

  • let me just say h bigger.

  • So this is x plus h.

  • That's what that point is right there.

  • So what going to be their corresponding y-coordinates

  • on the curve?

  • Well, this is the curve of y is equal to f of x.

  • So this point right here is going to be f of our

  • particular x right here.

  • And maybe to show you that I'm taking a particular x, maybe

  • I'll do a little 0 here.

  • This is x naught, this is x naught plus h.

  • This is f of x naught.

  • And then what is this going to be up here, this point up

  • here, that point up here?

  • Its y-coordinate is going to be f of f of this x-coordinate,

  • which I shifted over a little bit.

  • It's right there. f of this x-coordinate, which is

  • f of x naught plus h.

  • That's its y-coordinate.

  • So what is a slope going to be between these two points that

  • are relatively close to each other?

  • Remember, this isn't going to be the slope

  • just at this point.

  • This is the slope of the line between these two points.

  • And if I were to actually draw it out, it would actually be a

  • secant line between, to the curve.

  • So it would intersect the curve twice, once at this point,

  • once at this point.

  • You can't see it.

  • If I blew it up a little bit, it would look

  • something like this.

  • This is our coordinate x naught f of x naught, and up here

  • is our coordinate for this point, which would be, the

  • x-coordinate would be x naught plus h, and the y-coordinate

  • would be f of x naught plus h.

  • Just whatever this function is, we're evaluating it at this

  • x-coordinate That's all it is.

  • So these are the 2 points.

  • So maybe a good start is to just say, hey, what is the

  • slope of this secant line?

  • And just like we did in the previous example, you find the

  • change in y, and you divide that by your change in x.

  • Let me draw it here.

  • Your change in y would be that right here, change in y, and

  • then your change in x would be that right there.

  • So what is the slope going to be of the secant line?

  • The slope is going to be equal to, let's start with this

  • point up here, just because it seems to be larger.

  • So we want a change in y. so this value right here, this

  • y-value, is f of x naught plus h.

  • I just evaluated this guy up here.

  • Looks like a fancy term, but all it means is, look.

  • The slightly larger x evaluate its y-coordinate.

  • Where the curve is at that value of x.

  • So that is going to be, so the change in y is going to be

  • a f of x naught plus h.

  • That's just the y-coordinate up here.

  • Minus this y-coordinate over here.

  • So minus f of x naught.

  • So that equals our change in y.

  • And you want to divide that by your change in x.

  • So what is this?

  • This is the larger x-value.

  • We started with this coordinate, so we start

  • with its x-coordinate.

  • So it's x naught plus h, x naught plus h.

  • Minus this x-coordinate.

  • Well, we just picked a general number.

  • It's x naught.

  • So that is over your change in x.

  • Just like that.

  • So this is the slope of the secant line.

  • We still haven't answered what the slope is right at that

  • point, but maybe this will help us get there.

  • If we simplify this, so let me write it down like this.

  • The slope of the secant, let me write that properly.

  • The slope of the secant line is equal to the value of the

  • function at this point, f of x naught plus h, minus the value

  • of the function here, mine f of x naught.

  • So that just tells us the change in y.

  • It's the exact same definition of slope we've always used.

  • Over the change in x.

  • And we can simplify this.

  • We have x naught plus h minus x naught.

  • So x naught minus x naught cancel out, so you

  • have that over h.

  • So this is equal to our change in y over change in x.

  • Fair enough.

  • But I started off saying, I want to find the slope of

  • the line at that point, at this point, right here.

  • This is the zoomed-out version of it.

  • So what can I do?

  • Well, I defined second point here as just the first

  • point plus some h.

  • And we have something in our toolkit called a limit.

  • This h is just a general number.

  • It could be 10, it could be 2, it could be 0.02, it could be 1

  • times 10 to the negative 100.

  • It could be an arbitrarily small number.

  • So what happens, what would happen, at least theoretically,

  • if I were take the limit as h approaches 0?

  • So, you know, first, maybe h is this fairly large number over

  • here, and then if I take h a little bit smaller, then I'd be

  • finding the slope of this secant line.

  • If I took h to be even a little bit smaller, I'd be finding the

  • slope of that secant line.

  • If h is a little bit smaller, I'd be finding

  • the slope of that line.

  • So as h approaches 0, I'll be getting closer and closer to

  • finding the slope of the line right at my point in question.

  • Obviously, if h is a large number, my secant line is going

  • to be way off from the slope at exactly that point right there.

  • But if h is 0.0000001, if it's an infinitesimally small

  • number, then I'm going to get pretty close.

  • So what happens if I take the limit as h

  • approaches zero of this?

  • So the limit as h approaches 0 of my secant slope.

  • Of, let me switch to green.

  • f of x naught plus h minus f of x naught, that was my change in

  • y, over h, which is my change in x.

  • And now just to clarify something, and sometimes you'll

  • see it in different calculus books, sometimes instead of an

  • h, they'll write a delta x here.

  • Where this second point would have been defined as x naught

  • plus delta x, and then, this would have simplified to just

  • delta x over there, and we'd be taking the limit as

  • delta x approaches 0.

  • The exact same thing.

  • h, delta x, doesn't matter.

  • We're taking h as the difference between one x point

  • and then the higher x point, and then we're just going to

  • take the limit as that approaches zero.

  • We could have called that delta x just as easily.

  • But I'm going to call this thing, which equals the slope

  • of the tangent line, and it does equal the slope of the

  • tangent line, I'm going to call this the derivative of f.

  • Let me write that down.

  • And I'm going to say that this is equal to f prime of x.

  • And this is going to be another function.

  • Because remember, the slope changes at every x-value.

  • No matter what x-value you pick, the slope is

  • going to be different.

  • Doesn't have to be, but the way I drew this curve,

  • it is different.

  • It can be different.

  • So now, you give me an x-value in here, I'll apply this

  • formula over here, and then I can tell you the

  • slope at that point.

  • And it all seems very confusing and maybe

  • abstract at this point.

  • In the next video, I'll actually do an example of

  • calculating a slope, and it'll make it everything a

  • little bit more concrete.

We're first exposed to the idea of a slope of a line early on

字幕與單字

單字即點即查 點擊單字可以查詢單字解釋