Lec 19 | MIT 18.01 Single Variable Calculus, Fall 2007

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PROFESSOR: Today we're going to continue with integration.
And we get to do the probably the most important thing
of this entire course.
Which is appropriately named.
It's called the fundamental theorem of calculus.
And we'll be abbreviating it FTC and occasionally I'll put
in a 1 here, because there will be two versions of it.
But this is the one that you'll be using the
most in this class.
The fundamental theorem of calculus says the following.
It says that if F' = f, so F' ( x) = little f ( x), there's a
capital F and a little f, then the integral from a to b of
f ( x) = F ( b) - F (a).
That's it.
That's the whole theorem.
And you may recognize it.
Before, we had the notation that f was the antiderivative,
that is, capital F was the integral of f(x).
We wrote it this way.
This is this indefinite integral.
And now we're putting in definite values.
And we have a connection between the two uses
of the integral sign.
But with the definite values, we get real numbers out
instead of a function.
Or a function up to a constant.
So this is it.
This is the formula.
And it's usually also written with another notation.
So I want to introduce that notation to you as well.
So there's a new notation here.
Which you'll find very convenient.
Because we don't always have to give a letter f to
the functions involved.
So it's an abbreviation.
For right now there'll be a lot of f's, but anyway.
So here's the abbreviation.
Whenever I have a difference between a function at two
values, I also can write this as F ( x) with an a down
here and a b up there.
So that's the notation that we use.
And you can also, for emphasis, and this sometimes turns out to
be important, when there's more than one variable floating
around in the problem.
To specify that the variable is x.
So this is the same thing as x = a.
And x = b.
It indicates where you want to plug in, what
you want to plug in.
And now you take the top value minus the bottom value.
So F ( b) - F(a).
So this is just a notation, and in that notation, of course,
the theorem can be written with this set of symbols here.
Equally well.
So let's just give a couple of examples.
The first example is the one that we did last
time very laboriously.
If you take the function capital F(x), which happens
to be x^3 / 3, then if you differentiate it, you get,
well, the the factor of 3 cancels.
So you get x^2, that's the derivative.
And so by the fundamental theorem, so this implies by the
fundamental theorem, that the integral from say, a to b of
x^3 over - sorry, x^2 dx, that's the derivative here.
This is the function we're going to use as f ( x) here
= this function here.
F ( b) - F ( a), that's here.
This function here.
So that's write F(b) - F( a), and that's equal
to b^3 / 3 - a^3 / 3.
Now, in this new notation, we usually don't have
all of these letters.
All we write is the following.
We write the integral from a to be, and I'm going to do the
case 0 to b, because that was the one that we actually
did last time.
So I'm going to set a = 0 here.
And then, the problem we were faced last time as this.
And as I said we did it very laboriously.
But now you can see that we can do it in ten
seconds, let's say.
Well, the antiderivative of this is x^3 / 3.
I'm going to evaluate it at 0 and at b and subtract.
So that's going to be b^3 / 3 - 0^3 / 3.
Which of course is b^3 / 3.
And that's the end, that's the answer.
So this is a lot faster than yesterday.
I hope you'll agree.
And we can dispense with those elaborate computations.
Although there's a conceptual reason, a very important one,
for understanding the procedure that we went through.
Because eventually you're going to be using integrals and these
quick ways of doing things, to solve problems like finding
the volumes of pyramids.
In other words, we're going to reverse the process.
And so we need to understand the connection between the two.
I'm going to give a couple more examples.
And then we'll go on.
So the second example would be one that would be quite
difficult to do by this Riemann sum technique that we
described yesterday.
Although it is possible.
It uses much higher mathematics to do it.
And that is the area under one hump of the sine curve, sine x.
Let me just draw a picture of that.
The curve goes like this, and we're talking
about this area here.
It starts out at 0, it goes to pi.
That's one hump.
And so the answer is, it's the integral from
0 to pi of sin x dx.
And so I need to take the antiderivative of that.
And that's - cos x.
That's the thing whose derivative is sin x.
Evaluating it at 0 and pi.
Now, let's do this one carefully.
Because this is where I see a lot of arithmetic mistakes.
Even though this is the easy part of the problem.
It's hard to pay attention and plug in the right numbers.
And so, let's just pay very close attention.
I'm plugging in pi.
That's - cos pi.
That's the first term.
And then I'm subtracting the value at the bottom,
which is - cos 0.
There are already five opportunities for you to make
a transcription error or an arithmetic mistake
in what I just did.
And I've seen all five of them.
So the next one is that this is - (- 1).
Minus negative 1, if you like.
And then this is minus, and here's another - 1.
So altogether we have 2.
So that's it.
That's the area.
This area, which is hard to guess, this is area 2.
The third example is maybe superfluous but I'm
going to say it anyway.
We can take the integral, say, from 0 to 1, of x ^ 100.
Any power, now, is within our power.
So let's do it.
So here we have the antiderivative is
x ^ 101 / 101.
Evaluate it at 0 and 1.
And that is just 1 / 101.
That's that.
So that's the fundamental theorem.
Now this, as I say, harnesses a lot of what we've already
learned, all about antiderivatives.
Now, I want to give you an intuitive interpretation.
So let's try that.
We'll talk about a proof of the fundamental theorem
a little bit later.
It's not actually that hard.
But we'll give an intuitive reason, interpretation,
if you like.
Of the fundamental theorem.
So this is going to be one which is not related to
area, but rather to time and distance.
So we'll consider x (t) is your position at time t.
And then x' (t), which is dx/dt, is going to be what
we know as your speed.
And then what the theorem is telling us, is the following.
It's telling us the integral from a to b of v ( t) dt.
So, reading the relationship is equal to x (b) - x ( a).
And so this is some kind of cumulative sum
of your velocities.
So let's interpret the right-hand side first.
This is the distance traveled.
And it's also what you would read on your odometer.
Right, from the beginning to the end of the trip.
That's what you would read on your odometer.
Whereas this is what you would read on your speedometer.
So this is the interpretation.
Now, I want to just go one step further into this
interpretation, to make the connection with the Riemann
sums that we had yesterday.
Because those are very complicated to understand.
And I want you to understand them viscerally on
several different levels.
Because that's how you'll understand integration better.
The first thing that I want to imagine, so we're going to do a
thought experiment now, which is that you are
extremely obsessive.
And you're driving your car from time a to time b, place
q to place r, whatever.
And you check your speedometer every second.
OK, so you've read your speedometer in the i'th second,
and you've read that you're going at this speed.
Now, how far do you go in that second?
Well, the answer is you go this speed times the time interval,
which in this case we're imagining as 1 second.
So this is how far you went.
But this is the time interval.
And this is the distance traveled. in that a second
number, i, in the i'th second.
The distance traveled in the i'th second, that's a total
distance you traveled.
Now, what happens if you go the whole distance?
Well, you travel the sum of all these distances.
So it's some massive sum, where n is some ridiculous
number of seconds.
3600 seconds or something like that.
Whatever it is.
And that's going to turn out to be very similar to what you
would read on your odometer.
Because during that second, you didn't change
velocity very much.
So the approximation that the speed at one time that you
spotted it is very similar to the speed during
the whole second.
It doesn't change that much.
So this is a pretty good approximation to how
far you traveled.
And so the sum is a very realistic approximation
to the entire integral.
Which is denoted this way.
Which, by the fundamental theorem, is exactly
how far you traveled.
So this is x ( b) - x (a).
The other one is approximate.
OK, again this is called a Riemann sum.
Alright so that's the intro to the fundamental theorem.
And now what I need to do is extend it just a bit.
And the way I'm going to extend it is the following.
I'm going to do it on this example first.
And then we'll do it more formally.
So here's this example where we went someplace.
But now I just want to draw you an additional picture here.
Imagine I start here and I go over to there
and then I come back.
And maybe even I do a round trip.
I come back to the same place.
Well, if I come back to the same place, then the position
is unchanged from the beginning to the end.
In other words, the difference is 0.
And the velocity, technically rather than the speed.
It's the speed to the right and the the speed to the left maybe
are the same, but one of them is going in the positive
direction and one of them is going in the negative
direction, and they cancel each other.
So if you have this kind of situation, we want
that to be reflected.
We like that interpretation and we want to preserve it even
when in the case when the function v is negative.
And so I'm going to now extend our notion of integration.
So we'll extend integration to the case f negative.
Or positive.
In other words, it could be any sign.
Actually, there's no change.
The formulas are all the same.
We just, if this v is going to be positive, we write
in a positive number.
If it's going to be negative, we write in a negative number.
And we just leave it alone.
And the real, so here's, let me carry out an example
and show you how it works.
I'll carry out the example on this blackboard up here.
Of the sine function.
But we're going to try two humps.
We're going to try the first hump and the one that
goes underneath.
So our example here is going to be the integral from
0 to 2pi of sin x dx.
And now, because the fundamental theorem is so
important, and so useful, and so convenient, we just assume
that it be true in this case as well.
So we insist that this is going to be - cos x.
Evaluate it at 0 and 2pi.
With the difference.
Now, when we carry out that difference, what we get here
is - cos 2pi. - (- cos 0).
Which is - 1 - (- 1), which is 0.
And the interpretation of this is the following.
Here's our double hump, here's pi and here's 2pi.
And all that's happening is that the geometric
interpretation that we had before of the area under
the curve has to be taken with a grain of salt.
In other words, I lied to you before when I said that the
definite integral was the area under the curve.
It's not.
The definite integral is the area under the curve when it's
above the curve, and it counts negatively when it's
below the curve.
So yesterday, my geometric interpretation was incomplete.
And really just a plain lie.
So the true geometric interpretation of the definite
integral is plus the area above the axis, above the x
axis, minus the area below the x axis.
As in the picture.
I'm just writing it down in words, but you should think
of it visually also.
So that's the setup here.
And now we have the complete definition of integrals.
And I need to list for you a bunch of their properties and
how we deal with integrals.
So are there any questions before we go on?
So the question was, wouldn't the absolute value of the
velocity function be involved?
The answer is yes.
That is, that's one question that you could ask.
One question you could ask is what's the total
distance traveled.
And in that case, you would keep track of the absolute
value of the velocity as you said.
Whether it's positive or negative.
And then you would get the total length of
this curve here.
That's, however, not what the definite integral measures.
It measures the net distance traveled.
So it's another thing.
In other words, we can do that.
We now have the tools to do both.
We could also, so if you like, the total distance is equal
to the integral of this.
From a to b.
But the net distance is the one without the
absolute value signs.
So that's correct.
Other questions?
So now, let's talk about properties of integrals.
So the properties of integrals that I want to mention
to you are these.
The first one doesn't bear too much comment.
If you take the cumulative integral of a sum, you're just
trying to get the sum of the separate integrals here.
And I won't say much about that.
That's because sums come out, the because the
integral is a sum.
Incidentally, you know this strange symbol here,
there's actually a reason for it historically.
If you go back to old books, you'll see that it actually
looks a little bit more like an s.
This capital Sigma is a sum.
S for sum, because everybody in those days knew
Latin and Greek.
And this one is also an s, but gradually it was such
an important s that they made a bigger.
And then they stretched it out and made it a little thinner,
because it didn't fit into one typesetting space.
And so just for typesetting reasons it got stretched.
And got a little bit skinny.
Anyway, so it's really an s.
And in fact, in French they call it sum.
Even though we call it integral.
So it's a sum.
So it's consistent with sums in this way.
And similarly, similarly we can factor constants out of sums.
So if you have an integral like this, the constant factors out.
But definitely don't try to get a function out of this.
That won't happen.
OK, in other words, c has to be a constant.
Doesn't depend on x.
The third property.
What do I want to call the third property here?
I have sort of a preliminary property, yes, here.
Which is the following.
And I'll draw a picture of it.
I suppose you have three points along a line.
So then I'm going to draw a picture that.
And I'm going to use the interpretation above the
curve, even though that's not the whole thing.
So here's a, here's b and here's c.
And you can see that the area of this piece, of the first
two pieces here, when added together, gives you the
area of the whole.
And that's the rule that I'd like to tell you.
So if you integrate from a to b, and you add to that the
integral from b to c, you'll get the integral from a to c.
This is going to be just a little preliminary, because
the rule is a little better than this.
But I will explain that in a minute.
The fourth rule is a very simple one.
Which is that the integral from a to a of f ( x ) dx = 0.
Now, that you can see very obviously because
there's no area.
No horizontal movement there.
The rectangle is infinitely thin, and there's
nothing there.
So this is the case.
You can also interpret it a F ( a) - F ( a).
So that's also consistent with our interpretation.
In terms of the fundamental theorem of calculus.
And it's perfectly reasonable that this is the case.
Now, the fifth property is a definition.
It's not really a property.
But it's very important.
The integral from a to b of f( x) dx = minus the integral
from b to a, of f( x) dx.
Now, really, the right-hand side here is an undefined
quantity so far.
We never said you could ever do this where the a < b.
Because this is working backwards here.
But we just have a convention that that's the definition.
Whenever we write down this number, it's the same as
minus what that number is.
And the reason for all of these is again that we want them to
be consistent with the fundamental theorem
of calculus.
Which is the thing that makes all of this work.
So if you notice the left-hand side here is F ( b)
- F ( a), capital F.
The antiderivative of little f.
On the other hand, the other side is minus, and if we just
ignore that, we say these are letters, if we were a machine,
we didn't know which one was bigger than which, we just
plugged them in, we would get here F( a) - F( b), over here.
And to make these two things equal, what we want is to
put that minus sign in.
Now it's consistent.
So again, these rules are set up so that everything
is consistent.
And now I want to improve on rule 3 here.
And point out to you.
So let me just go back to rule 3 for a second.
That now that we can evaluate integrals regardless of the
order, we don't have to have a < b, b < c in order to
make sense out of this.
We actually have the possibility of considering
integrals where the a's and the b's and the c's are
in any order you want.
And in fact, with this definition, with this
definition 5, 3 works no matter what the numbers are.
So this is much more convenient.
We don't, this is not necessary.
Not necessary.
It just works using convention 5.
OK, with 5.
Again, before I go on, let me emphasize we really
want to respect the sign of this velocity.
We really want the net change in the position.
And we don't want this absolute value here.
Because otherwise, all of our formulas are going to mess up.
We won't always be able to check.
Sometimes you have letters rather than actual numbers
here, and you won't know whether a is bigger than b.
So you'll want to know that these formulas work and are
consistent in all situations.
OK, I'm going to trade these again.
In order to preserve the ordering 1 through 5.
And now I have a sixth property that I want to talk about.
This one is called estimation.
And it says the following. if f(x) <= g ( )x, then the
integral from a to b of f(x) dx <= the integral from
a to b of g (x) dx.
Now, this one says that if I'm going more slowly than you,
then you go farther than I do.
That's all it's saying.
For this one, you'd better have a < b.
You need it.
Because we flip the signs when we flip the order of a and b.
So this one, it's essential that the lower limit be
smaller than the upper limit.
But let me just emphasize, because we're dealing with
the generalities of this.
Actually if one of these is negative and the other one is
negative, then it also works.
This one ends up being, if f is more negative than g, then
this added up thing is more negative than that one.
Again, under the assumption that a < b.
So as I wrote it's in full generality.
Let's illustrate this one.
And then we have one more property to learn after that.
So let me give you an example of estimation.
The example is the same as one that I already gave you.
But this time, because we have the tool of integration, we
can just follow our noses and it works.
I start with the inequality, so I'm trying to illustrate
estimation, so I want to start with an inequality which is
what the hypothesis is here.
And I'm going to integrate the inequality to
get this conclusion.
And see what conclusion it is.
The inequality that I want to take is that e
^ x >= 1, for x >= 0.
That's going to be our starting place.
And now I'm going to integrate it.
That is, I'm going to use estimation to
see what that gives.
Well, I'm going to integrate, say, from 0 to b.
I can't integrate below 0 because it's only true above 0.
This is e ^ x dx >= the integral from 0 to b of 1 dx.
Alright, let's work out what each of these is.
The first one, e ^ x dx, is, the antiderivative is e ^
x, evaluated at 0 and b.
So that's e ^ b - e ^ 0.
Which is e ^ b - 1.
The other one, you're supposed to be able to get by
the rectangle law.
This is one rectangle of base b and height 1.
So the answer is b.
Or you can do it by antiderivatives, but it's b.
That means that our inequality says if I just combine these
two things together, that e ^ b - 1 >= b.
And that's the same thing as e ^ b >= 1 + b.
Again, this only works for b >= 0.
Notice that if b were negative, this would be a well
defined quantity.
But this estimation would be false.
We need that the b > 0 in order for this to make sense.
So this was used.
And that's a good thing, because this
inequality is suspect.
Actually, it turns out to be true when b is negative.
But we certainly didn't prove it.
I'm going to just repeat this process.
So let's repeat it.
Starting from the inequality, the conclusion, which
is sitting right here.
But I'll write it in a form e ^ x >= 1 + x, for x >= 0.
And now, if I integrate this one, I get the integral from 0
to b, e ^ x dx >= the integral from 0 to b, (1 + x) dx and I
remind you that we've already calculated this one.
This is e ^ b - 1.
And the other one is not hard to calculate.
The antiderivative is x + x^2 / 2.
We're evaluating that at 0 and b.
So that comes out to be b + b^2 / 2.
And so our conclusion is that the left side, which is e
^ b - 1 >= b + b^2 / 2.
And this is for b >= 0.
And that's the same thing as e ^ b >= 1 + b + b^2 / 2.
This one actually is false for b negative, so that's something
that you have to be careful with the b positives here.
So you can keep on going with this, and you
didn't have to think.
And you'll produce a very interesting polynomial,
which is a good approximation to e^ b.
So so that's it for the basic properties.
Now there's one tricky property that I need to tell you about.
It's not that tricky, but it's a little tricky.
And this is change of variables.
Change of variables in integration, we've
actually already done.
We called that, the last time we talked about it,
we called it substitution.
And the idea here, if you may remember, was that if you're
faced with an integral like this, you can change it to, if
you put in u = u (x) and you have a du, which is equal
to u' ( x) du, dx, sorry.
Then you can change the integral as follows.
This is the same as g (u( x)) u' (x) dx.
This was the general procedure for substitution.
What's new today is that we're going to put in the limits.
If you have a limit here, u1, and a limit here, u2, you want
to know what the relationship is between the limits here and
the limits when you change variables to the new variables.
And it's the simplest possible thing.
Namely the two limits over here are in the same relationship as
u ( x) is to this symbol u here.
In other words, u1 = u ( x1), and u2 = u(x2).
That's what works.
Now there's only one danger here, there's subtlety which
is, this only works if u' does not change sign.
I've been worrying a little bit about going backwards and
forwards, and I allowed myself to reverse and do all kinds of
stuff, right, with these integrals.
So we're sort of free to do it.
Well, this is one case where you want to avoid it, OK?
Just don't do it.
It is possible, actually, to make sense out of it, but it's
also possible to get yourself infinitely confused.
So just make sure that -- now it's OK is u' is always
negative, or always going one way, so OK if u' is always
positive, you're always going the other way, but if you mix
them up you'll get yourself mixed up.
Let me give you an example.
The example will be maybe close to what we did last time.
When we first did substitution.
So the integral from 1 to 2, this time I'll put in definite
limits, of x^2 plus -- sorry, maybe I call this x^3. x^3 +
2, let's say, I don't know, to the 5th power, x^2 dx.
So this is an example of an integral that we would
have tried to handle by substitution before.
And the substitution we would have used is u = x^3 + 2.
And that's exactly what we're going to do here.
But we're just going to also take into account the limits.
The first step as in any substitution or change
of variables, is this.
And so we can fill in the things that we would
have done previously.
Which is that this is the integral and this is u ^ 5.
And then because this is 3x^2, we see that this is 3.
Sorry, let's write it the other way.
1/3 du = x^2 dx.
So that's what I'm going to plug in for this factor here.
So here's 1/3 du, which replaces that.
But now there's the extra feature.
The extra feature is the limits.
So here, really in disguise, because, and now this is
incredibly important.
This is one of the reasons why we use this notation dx and du.
We want to remind ourselves which variable is involved
in the integration.
And especially if you're the one naming the variables, you
may get mixed up in this respect.
So you must know which variable is varying between 1 and 2.
And the answer is, it's x is the one that's
varying between 1 and 2.
So in disguise, even though I didn't write it, it
was contained in this little symbol here.
This reminded us which variable.
You'll find this amazingly important when you get to
multivariable calculus.
When there are many variables floating around.
So this is an incredibly important distinction to make.
So now, over here we have a limit.
But of course it's supposed to be with respect to u, now.
So we need to calculate what those corresponding limits are.
And indeed it's just, I plug in here u1 is going to be able to
what I plug in for x = 1, that's going to be 1
^3 + 2, which is 3.
And then u2 is 2^3 + 2, which = 10, right?
8 + 2 = 10.
So this is the integral from 3 to 10, of u ^ 5 (1/3 du).
And now I can finish the problem.
This is 1/18 u ^ 6, from 3 to 10.
And this is where the most common mistake occurs in
substitutions of this type.
Which is that if you ignore this, and you plug in these 1
and 2 here, you think, oh I should just be putting
it at 1 and 2.
But actually, it should be, the u value that we're interested
in, and the lower limit is u = 3 and u = 10 as
the upper limit.
So those are suppressed here.
But those are the ones that we want.
And so, here we go.
It's 1/18 times some ridiculous number which I won't calculate.
10 ^ 6 - 3 ^ 6.
Yes, question.
PROFESSOR: So, if you want to do things with where you're
worrying about the sign change, the right strategy is,
what you suggested works.
And in fact I'm going to do an example right
now on this subject.
But, the right strategy is to break it up into pieces.
Where u' has one sign or the other, OK?
Let me show you an example.
Where things go wrong.
And I'll tell you how to handle it roughly.
So here's our warning.
Suppose you're integrating for - 1 to 1, x^2 dx.
Here's an example.
And you have the temptation to plug in u = x^2.
Now, of course, we know how to integrate this.
But let's just pretend we were stubborn and wanted
to use substitution.
Then we have du = 2x dx.
And now if I try to make the correspondence, notice that
the limits are u1 = (- 1)^2, that's the bottom limit.
And u2 is the upper limit.
That's 1 ^2, that's also equal to 1.
Both limits are 1.
So this is going from 1 to 1.
And no matter what it is, we know it's going to be 0.
But we know this is not 0.
This is the integral of a positive quantity.
And the area under a curve is going to be a positive area.
So this is a positive quantity.
It can't be 0.
If you actually plug it in, it looks equally strange.
You put in here this u and then, so that
would be for the u^2.
And then to plug in for dx, you would write dx = (1 / 2x) du.
And then you might write that as this.
And so what I should put in here is this quantity here.
Which is a perfectly OK integral.
And it has a value, I mean, it's what it is.
It's 0.
So of course this is not true.
And the reason is that u = x^2, and u' ( x ) = 2x, which was
positive for x positive, and negative for x negative.
And this was the sign change which causes us trouble.
If we break it off into its two halves, then it'll be OK and
you'll be able to use this.
Now, there was a mistake.
And this was essentially what you were saying.
That is, it's possible to see this happening as you're doing
it if you're very careful.
There's a mistake in this process, and the mistake
is in the transition.
This is a mistake here.
Maybe I haven't used any red yet today, so I get
to use some red here.
Oh boy.
This is not true, here.
This step here.
So why isn't it true?
It's not true for the standard reason.
Which is that really, x = plus or minus square root of u.
And if you stick to one side or the other, you'll have
a coherent formula for it.
One of them will be the plus and one of them will be the
minus and it will work out when you separate
it into its pieces.
So you could do that.
But this is a can of worms.
So I avoid this.
And just do it in a place where the inverse is well defined.
And where the function either moves steadily
up or steadily down.