-
-
DR. MAGDALENA TODA: Sorry.
-
I really don't mind if you
walk in a little bit late.
-
I know that you guys come
from other buildings,
-
and some professors
keep you overtime.
-
So as long as you
quietly enter the room,
-
I have no problem with
walking in a little bit late.
-
Would anybody want to
start an attendance sheet?
-
Who wants to be the one?
-
Roberto, please.
-
Thank you so much.
-
All right.
-
We went through chapter
12 on Monday fast.
-
And I would like to start with
a review of 12.1, 12.2, 12.3.
-
So two thing we will do today.
-
Part one will be review of
chapter 12, sections to 12.1,
-
12.3 from the book and
starting chapter 12,
-
section 12.4 today later.
-
What is that about?
-
This is about the surface
integrals, surface area,
-
and [INAUDIBLE].
-
-
All right.
-
What have you seen
in 12.1, 12.3?
-
Let's review quickly
what you've learned.
-
You've learned about
how to interpret
-
an integral with a positive
function that is smooth.
-
Well, we said
continuous-- that would
-
be enough-- over a
rectangular region.
-
And the geometric meaning
of such a problem,
-
integrate f of x, y positive
over a domain was what?
-
The volume of a body under the
graph and above that domain,
-
so projected down, protecting
down on the domain.
-
Evaluate that body.
-
How did we do it?
-
Double integral of f
of x, y, dxdy or dA.
-
But then we said, OK, if you
have a rectangular region
-
on the ground, then it's easy.
-
You apply the Fubini theorem.
-
And then you'll have
integral from A to B,
-
integral from C to
D, fixed end points.
-
When you didn't have
a rectangular region
-
to integrate over, you
would have such a type one,
-
type two regions, who
are easy to deal with,
-
which were the case of regions
like the ones between two
-
straight lines
and two functions.
-
And then you had the type
two, two straight lines
-
and two functions,
where the functions
-
were assumed differentiable
actually in our examples.
-
Type one, type two.
-
What did we do after that?
-
After that, we said, well,
what if you're not so lucky
-
and have such nice domains?
-
Or maybe you have
something with a corner.
-
What do you do if
you have a corner?
-
Well, you'd still be able to
divide the surface into two,
-
where you have two
separate areas.
-
And then you integrate on them
separately at the same time.
-
And you have an
additive integral.
-
The integral would be additive.
-
Those are easy to deal with.
-
Well, what if you had something
that is more sophisticated,
-
like a disk or an annulus?
-
And in that case, it's
really a big headache,
-
considering how to do this
using one of the previous steps.
-
So we had to introduce
polar coordinates.
-
And we have to
think, what change
-
do I have from x, y to r,
theta, polar coordinates
-
back and forth?
-
And when we did the double
integral over a domain f of x,
-
y function positive dA in
the Cartesian coordinates.
-
When we switched to
polar coordinates,
-
we had a magic thing
happen, which was what?
-
Some f of x of r,
theta, y of r, theta.
-
I say theta.
-
I put phi.
-
It doesn't matter.
-
Let me put theta if
you prefer theta.
-
A change of
coordinates, a Jacobian.
-
That was what?
-
Do you guys remember that?
-
r.
-
Very good.
-
I'm proud of you, r.
-
And then drd theta.
-
So you're ready do that
kind of homework, integrals,
-
double integrals in
polar coordinates.
-
dr will be between
certain values,
-
hopefully fixed
values because that
-
will make the Fubini-Tonelli
a piece of cake.
-
Theta, also fixed values.
-
But not always will you have
fixed values, especially
-
in the first part.
-
You may have some function
of r, function of r.
-
And here, theta 1 and theta 2.
-
So I want to see a
few more examples
-
before I move on to section 12.4
because, as the Romans said,
-
review is the
mother of studying,
-
which is [LATIN], which means
go ahead and do a lot of review
-
if you really want to
master the concepts.
-
-
OK.
-
I'm going to take the plunge
and go ahead and help you
-
with your homework.
-
I've been pondering
about this a lot.
-
We've done problems that I made
up, like the ones in the book.
-
And I also took problems
straight out of the book.
-
But I would like to go over
some homework type problems
-
in order to assist you in more
easily doing your homework.
-
-
In chapter 12, homework
four-- am I right,
-
homework number four?
-
You have a big array of
problems, all sorts of problems
-
because mathematicians
have all sorts of problems.
-
For example, an easy
one that you're not
-
going to have a problem with--
and I'm using my own end
-
points.
-
Your end points may be
different in the homework.
-
It would be homework four,
chapter 12, number four.
-
And you say-- most of
you should say, oh,
-
that's a piece of cake.
-
I don't know why she even talks
about such a trivial problem,
-
right?
-
Many of you have said that.
-
Well, I am willing
to review everything
-
so that you have a better
grasp of the material.
-
On this one, since it's so
easy, I want you to help me.
-
What kind of problem is that?
-
As I said, mathematicians have
all sorts of problems, right?
-
So a problem where you
have a product inside
-
as an integrand, where the
variables are completely
-
separated-- what does it mean?
-
The function
underneath is a product
-
of two functions, one
function of x only,
-
the other function
of y only, which
-
is a blessing in disguise.
-
Why is that a blessing?
-
I told you last time that you
can go ahead and write this
-
as product of integrals.
-
Is there anybody seeing already
what those integrals will be?
-
Let's see how much you
mastered the material.
-
STUDENT: x over 2y times--
-
DR. MAGDALENA TODA:
From 1 to 2, you said?
-
STUDENT: Yeah, from 1 to 2.
-
I'm sorry.
-
DR. MAGDALENA TODA: Of what?
-
X, dx times the integral
from 0 to pi of what?
-
STUDENT: Cosine y.
-
DR. MAGDALENA TODA: Cosine y.
-
Do we need to
re-prove this result?
-
No, we proved it last time.
-
But practically, if
you forget, the idea
-
is a very simple thing.
-
When you integrate
with respect to y,
-
Mr. X said, I'm
not married to y.
-
I'm out of here.
-
I'm out of the picture.
-
I'm going for a walk.
-
So the integral of cosine is
in itself to be treated first,
-
independently.
-
And it's inside,
and it's a constant.
-
And it pulls out in the end.
-
And since it pulls
out, what you're
-
going to be left with afterwards
will be that integral of 1
-
to 2x dx.
-
So we've done that
last time as well.
-
Yes, sir?
-
STUDENT: So you
would-- would you
-
not be able to do that
if it was cosine x, y?
-
DR. MAGDALENA TODA: Absolutely.
-
If you had cosine
x, y, it's bye, bye.
-
STUDENT: So it's only when
they're completely separate--
-
DR. MAGDALENA TODA: When
you are lucky enough
-
to have a functional of only
that's a function of y only.
-
And if you had another
example, sine of x plus y,
-
anything that mixes them up--
that would be a bad thing.
-
Do I have to compute this?
-
Not if I'm smart.
-
At the blink of an eye,
I can sense that maybe I
-
should do this one first.
-
Why?
-
Integral of cosine is sine.
-
And sine is 0 at both 0 and pi.
-
So it's a piece of pie.
-
So if I have 0, and
the answer is 0.
-
So you say, OK,
give us something
-
like that on the midterm
because this problem is
-
a piece of cake.
-
Uh, yeah.
-
I can do that.
-
Probably you will have something
like that on the midterm,
-
on the April 2 midterm.
-
So since Alex just
entered, I'm not
-
going to erase this for a while
until you are able to copy it.
-
I announced starting the
surface area integral today.
-
Section 12.4, we'll
do that later on.
-
And I will move on to
another example right now.
-
Oh, now they learn.
-
Look, they learned about me.
-
They learned about me,
that I have lots of needs.
-
And I don't complain.
-
But they noticed that these
were disappearing really fast.
-
Everybody else told me that
I write a lot on the board,
-
compared to other professors.
-
So I don't know if that is true.
-
But I really need
this big bottle.
-
OK.
-
-
So you can actually
solve this by yourself.
-
You just don't realize it.
-
I'm not going to take
any credit for that.
-
And I'm going to go ahead
and give you something
-
more challenging, see if
you are ready for the review
-
and for the midterm.
-
OK.
-
That's number nine
on your homework
-
that may have again
the data changed.
-
But it's the same
type of problem.
-
Now you cannot ask me about
number nine anymore directly
-
from WeBWork, because I'll
say, I did that in class.
-
And if you have
difficulty with it,
-
that means you did
not cover the notes.
-
-
This is pretty.
-
You've seen that one before.
-
And I would suspect
that you're not
-
going to even let me
talk, because look at it.
-
Evaluate the following integral.
-
-
And it doesn't
matter what numbers
-
we are going to put on that
and what funny polynomial I'm
-
going to put here.
-
-
You are going to have
all sorts of numbers.
-
Maybe these are not
the most inspired ones,
-
but this is WeBWork.
-
It creates problems at
random, and every student
-
may have a different
problem, that is,
-
in order to minimize cheating.
-
And that's OK.
-
The type of the problem
is what matters.
-
So if we were in
Calc 1 right now,
-
and somebody would say, go
ahead and take an integral of e
-
to the x squared dx and compute
it by hand, see what you get,
-
you already know.
-
They don't know, poor people.
-
They don't know.
-
But you know because I told
you that this is a headache.
-
-
You need another way out.
-
You cannot do that in Calc 2.
-
And you cannot do that in
an elementary way by hand.
-
This is something that MATLAB
would solve numerically for you
-
in no time if you gave
certain values and so on.
-
But to find an explicit
form of that anti-derivative
-
would be a hassle.
-
The same thing would happen
if I had the minus here.
-
In that case, I wouldn't be able
to express the anti-derivative
-
as an elementary
function at all.
-
OK.
-
So this is giving
me a big headache.
-
I'm going to make a face.
-
And I'll say, oh, my god.
-
I get a headache.
-
Unless you help me get out of
trouble, I cannot solve that.
-
MATLAB can do that for me.
-
On Maple, I can go in and
plug in the endpoints and hope
-
and pray that I'm
going to get the best
-
numerical approximation
for the answer.
-
But what if I want a precise
answer, not a numerical answer?
-
Then I better put my
mind, my own mind,
-
my own processor to work and
not rely on MATLAB or Maple.
-
OK.
-
Hmm.
-
Understandable, precise answer.
-
And I leave it unsimplified
hopefully, yes.
-
We need to think of what
technique in this case?
-
STUDENT: Changing the order.
-
DR. MAGDALENA TODA: Change
the order of integration.
-
OK.
-
All right.
-
And in that case, the
integrand stays the same.
-
-
These two guys are
swapped, and the end points
-
are changing
completely because I
-
will have to switch from one
domain to the other domain.
-
The domain that's given here by
this problem is the following.
-
x is between 7y 7, and
y is between 0 and 1.
-
So do they give you horizontal
strip or vertical strip domain?
-
-
Horizontal.
-
Very good.
-
I wasn't sure if
I heard it right.
-
But anyway, what is this
function and that function?
-
So x equals 7 would be what?
-
x equals 7 will be far away.
-
I have to do one, two, three,
four-- well, five, six, seven.
-
Then is a vertical
line. x equals 7.
-
That's the x-axis.
-
That's the y-axis.
-
I'm trying to draw the domain.
-
And what is x equals 7y?
-
X equals 7y is the
same as y equals 1/7x.
-
Uh-huh.
-
That should be a
friendlier function
-
to draw because I'm smart
enough to even imagine
-
what it looks like.
-
y equals mx is a line that
passes through the origin.
-
It's part of a pencil of planes.
-
A pencil of planes is infinitely
many-- pencil of lines,
-
I'm sorry.
-
Infinitely many lines that all
pass through the same point.
-
So they all pass
through the origin.
-
For 7, x equals 7 is going
to give me y, 1, y equals 1.
-
So I'm going to erase this
dotted line and draw the line.
-
This is y equals x/7,
and we look at it,
-
and we think how nice
it is and how ugly it
-
is because it's [? fat ?].
-
It's not a straight line.
-
-
Now it looks straighter.
-
So simply, I get to 1, y equals
1 here, which is good for me
-
because that's
exactly what I wanted.
-
I wanted to draw the horizontal
strips for y between 0 and 1.
-
I know I'm going
very slow, but that's
-
kind of the idea
because-- do you
-
mind that I'm going so slow?
-
OK.
-
This is review for the
midterm slowly, a little bit.
-
So y between 0 and 1.
-
I'm drawing the
horizontal strips,
-
and this is exactly
what you guys have.
-
This is the red domain.
-
Let's call it d.
-
It's the same domain but
with horizontal strips.
-
And I'm going to
draw the same domain.
-
What color do you like?
-
I like green because it's
in contrast with red.
-
I'm going to use green to
draw the vertical strip domain
-
and say, all right.
-
Now I know what I'm
supposed to say,
-
that d with vertical strips is
going to be x between-- what?
-
Yes.
-
First the fixed
numbers, 0 and 7.
-
And y between--
-
-
STUDENT: 0 and x plus 7.
-
STUDENT: And 1.
-
-
DR. MAGDALENA TODA: This one.
-
x/7, 1/7x.
-
Right?
-
Is it x/7?
-
x/7y equals x is the same
thing as y equals x/7.
-
So y equals x/7 is
this problem, which was
-
the same as x equals 7y before.
-
OK.
-
So how do I set up
the new integral?
-
I'm going to say dydx, and then
y will be between 0 and x/7.
-
And x will be between 0 and 7.
-
-
Is it solved?
-
No.
-
But I promise from my heart that
if you do that on the midterm,
-
you'll get 75% on this
problem, even if doesn't say
-
don't compute it.
-
If it says, don't compute
it or anything like that,
-
you got 100%.
-
OK?
-
So this is the most
important step.
-
From this on, I know
you can do it with what
-
you've learned in Calc 1 and 2.
-
It's a piece of cake, and you
should do it with no problem.
-
Now how are we going
to handle this fellow?
-
This fellow says, I have nothing
to do with you, Mr. Y. I'm out,
-
and you're alone.
-
I don't need you as my friend.
-
I'm out.
-
I'm independent.
-
So Mr. Y starts sulking.
-
And say I have an integral
of 1dy between 0 and x/7.
-
I'm x/7.
-
So you are reduced to
a very simple integral.
-
That is the integral that you
learned in-- was it Calc 1?
-
Calc 1, yes, the end of Calc 1.
-
All right.
-
So you don't need
the picture anymore.
-
You've done most of
the work, and you say,
-
I have an integral from 0 to
7, x over-- so this guy-- which
-
one shall I put first?
-
It doesn't matter.
-
e to the x squared
got out first.
-
He said, I'm out.
-
And then the integral of
1dy was y between these two,
-
so it's x/7 dx.
-
And this is a 7.
-
-
All right.
-
We are happy.
-
So what happens?
-
1/7 also goes for a walk.
-
And xdx says, OK, I need
to think about who I am.
-
I have to find my own
identity because I
-
don't know who I am anymore.
-
So he says, I need
a u substitution.
-
u substitution is
u equals x squared.
-
du equals 2xdx.
-
So xdx says, I know at least
that I am a differential
-
form, a 1 form, which is du/2.
-
And that's exactly what you
guys need to change the inputs.
-
1/7 was a [? custom ?].
-
He got out of here.
-
But you have to think,
when x is 0, what is u?
-
0.
-
When x is 7, what is u?
-
49.
-
Even my son would know this one.
-
He would know more.
-
He would know
fractions and stuff.
-
OK.
-
So e to the u.
-
-
And the 1/7 was out.
-
But what is xdx?
-
du/2.
-
So I'll say 1/2 du.
-
-
Are you guys with me?
-
Could you follow everything?
-
Yes.
-
It shouldn't be a problem.
-
Now 1/7 got out.
-
1/2 gets out.
-
Everybody gets out.
-
And the guy in the middle who is
left alone, the integral from e
-
to the u du-- what is he?
-
e to the u.
-
Between what values?
-
Between 49 and 0.
-
So I'm going to--
shall I write it again?
-
I'm too lazy for that.
-
e to the u-- OK, I'll write it.
-
e to the u between 49 and 0.
-
So I have 1/14, parentheses,
e to the 49 minus e to the 0.
-
That's a piece of cake.
-
1.
-
OK, so presumably if you
answered that in WeBWork,
-
this the precise answer.
-
Finding it correctly, you
would get the right answer.
-
Of course, you could do
that with the calculator.
-
MATLAB could do it for you.
-
Maple could do it for you.
-
Mathematica could do it for you.
-
But they will come up
with a numerical answer,
-
an approximation.
-
And you haven't learned
anything in the process.
-
Somebody just served you
the answer on a plate,
-
and that's not the idea.
-
-
Is this hard?
-
I'm saying on the midterm that's
based on the double integral
-
with switching order integrals,
this is as hard as it can get.
-
It cannot get worse than that.
-
So that will tell you about
the level of the midterm that's
-
coming up on the 2nd of April,
not something to be worried
-
about.
-
Do you need to learn a little
bit during the spring break?
-
Maybe a few hours.
-
But I would not worry my
family about it and say,
-
there is this witch.
-
And I'm going back
to [? Lubbock ?],
-
and I have to take
her stinking midterm.
-
And that stresses me out, so I
cannot enjoy my spring break.
-
By all means, enjoy
your spring break.
-
And just devote a few
hours to your homework.
-
But don't fret.
-
Don't be worried
about the coming exam,
-
because you will be prepared.
-
And I'm going to do
more review so that you
-
can be confident about it.
-
Another one.
-
Well, they're all easy.
-
But I just want to help you
to the best of my extent.
-
-
One more.
-
Here also is-- I don't-- OK.
-
Let's take this one because
it's not computational.
-
And I love it.
-
It's number 14.
-
Number 14 and number 15
are so much the same type.
-
And 16.
-
It's a theoretical problem.
-
It practically tests if
you understood the idea.
-
That's why I love this problem.
-
And it appears
obsessively, this problem.
-
I saw it in-- I've
been here for 14 years.
-
I've seen it at least on 10
different finals, the same type
-
of theoretical problem.
-
So it's number 14
over homework four.
-
Find an equivalent integral
with the order of integration
-
reversed.
-
So you need to
reverse some integral.
-
And since you are so savvy about
reversing the ordered integral,
-
you should not have
a problem with it.
-
-
And WeBWork is
asking you to fill
-
in the following expressions.
-
You know the type.
-
f of y, you have to
type in your answer.
-
And g of y, to type
in your answer.
-
-
OK.
-
So you're thinking, I know
how to do this problem.
-
It must be the idea as before.
-
This integral should
be-- according
-
to the order of
integration, it should
-
be a vertical strip thing
switching to a horizontal strip
-
thing.
-
And once I draw the domain,
I'm going to know everything.
-
And the answer is, yes,
you can do this problem
-
in about 25 seconds.
-
The moment you've learned
it and understood it,
-
it's going to go very smoothly.
-
And to convince
you, I'm just going
-
to go ahead and say, 0 and 1.
-
And draw, Magdalena.
-
You know how to draw.
-
Come on.
-
OK.
-
From 1-- 1, 1, right?
-
Is this the corner-- does
it look like a square?
-
Yes.
-
So the parabola y equals x
squared is the bottom one.
-
Am I right?
-
That is the bottom one, guys?
-
But when you see-- when
you are between 0 and 1,
-
x squared is a lot less
than the square root of x.
-
The square root of x is the
top, is the function on top.
-
And then you say, OK, I
got-- somebody gave me
-
the vertical strips.
-
I'll put the [INAUDIBLE],
but I don't need them.
-
I'll just go ahead
and take the purple,
-
and I'll draw the
horizontal strips.
-
And you are already
there because I
-
see the light in your eyes.
-
So tell me what you
have. y between n--
-
STUDENT: 0 and 1.
-
DR. MAGDALENA TODA: 0 and 1.
-
Excellent.
-
And y between what and x?
-
Oh, sorry, guys.
-
I need to protect my hand.
-
That's the secret recipe.
-
x is between a function of y.
-
Now what's the
highest function of y?
-
STUDENT: Square root of y.
-
DR. MAGDALENA TODA:
Square root of y.
-
And who is that fellow?
-
This one.
-
x equals square root
of y, the green fellow.
-
I should have written in
green, but I was too lazy.
-
And this one is going to
be just x equals y squared.
-
So between y square
down, down, down, down.
-
Who is down? f is down.
-
Right, guys?
-
The bottom one is f.
-
The bottom one is y squared.
-
The upper one is the
square root of y.
-
You cannot type that
in WeBWork, right?
-
You type sqrt, what?
-
y, caret, 2.
-
And here, what do you have?
-
0 and 1.
-
So I talk too much.
-
But if you were on your
own doing this in WeBWork,
-
it would take you no
more than-- I don't
-
know-- 60 seconds to type in.
-
Remember this problem
for the midterm.
-
It's an important idea.
-
And you've seen it emphasized.
-
You will see it emphasized
in problems 14, 15, 16.
-
It's embedded in this
type of exchange,
-
change the order of
integration type problem.
-
-
OK?
-
Anything else I would like
to show you from-- there
-
are many things I
would like to show you.
-
But I better let you
do things on your own.
-
How about 17, which is a
similar type of problem,
-
theoretical, just like this one?
-
But it's testing
if you know the--
-
if you understood the idea
behind polar integration,
-
integration in
polar coordinates.
-
Can I erase?
-
OK.
-
So let's switch to number
17 from your homework.
-
-
Write down the problems
we are going over,
-
so when you do
your homework, you
-
refer to your lecture notes.
-
This is not a lecture.
-
What is this, what
you're doing now?
-
It's like-- what is this?
-
An application session,
a problem session.
-
OK.
-
Number 17, homework four.
-
On this one, unfortunately
I'm doing just your homework
-
because there is no data.
-
So when-- it's the unique
problem you're going to get.
-
You have a picture, and that
picture looks like that.
-
From here, [INAUDIBLE]
a half of an annulus.
-
-
You have half of a ring.
-
And it says, suppose that
r is the shaded region
-
in the figure.
-
As an iterated integral
in polar coordinates,
-
the double integral
over R f of x, y dA
-
is the integral from A to
B of the integral from C
-
to B of f of r, theta times r
drd theta with the following
-
limits of integration.
-
A. And WeBWork says, you say it.
-
You say.
-
It's playing games with you.
-
B, you say.
-
It's a guessing game.
-
C, you say.
-
Then D, you say it.
-
And let's see what you say.
-
-
Well, we say, well,
how am I going to go?
-
I have to disclose
the graphing paper.
-
They are so mean.
-
They don't show you
the actual numbers.
-
They only give you
graphing paper.
-
I'm not good at graphing, OK?
-
So you will have to
guess what this says.
-
That should be good enough.
-
Perfect.
-
So the unit supposedly
is this much.
-
1 inch, whatever.
-
I don't care.
-
So is it hard?
-
It's a piece of cake.
-
It's a 10 second problem.
-
It's a good problem for the
midterm because it's fast.
-
-
Theta is a wonderful angle.
-
-
It is nice to look at.
-
And they really don't
put numbers here?
-
They do.
-
They do on the margin
of the graphing paper.
-
They have a scale.
-
OK.
-
So come on.
-
This is easy.
-
You guys are too smart
for this problem.
-
From what to what?
-
STUDENT: [INAUDIBLE].
-
DR. MAGDALENA TODA: Nope.
-
No, that's a problem.
-
So when we measure
the angle theta,
-
where do we start measuring?
-
STUDENT: 0.
-
DR. MAGDALENA TODA: Over here.
-
So we go down there
clockwise because that's
-
how we mix in the bowl,
counter-clockwise.
-
So 0-- so this is
going to be pi.
-
Pi.
-
-
And what is the end?
-
STUDENT: 2 pi.
-
DR. MAGDALENA TODA: 2 pi.
-
2 pi.
-
-
Don't type-- oh, I mean, you
cannot type the symbol part,
-
right?
-
And then what do you
type, in terms of C and D?
-
STUDENT: [INAUDIBLE]
-
DR. MAGDALENA TODA: Nope.
-
No, no.
-
The radius is positive only.
-
STUDENT: 0 to 1.
-
DR. MAGDALENA TODA: 1 to 2.
-
Why 1 to 2?
-
Excellent.
-
Because the shaded area
represents the half of a donut.
-
You have nothing inside.
-
There is a whole in
here, in the donut.
-
So between 0 and 1,
you have nothing.
-
And the radius-- take
a point in your domain.
-
It's here.
-
The radius you
have, the red radius
-
you guys see on the picture is
a value that's between 1 and 2,
-
between 1 and 2.
-
And that's it.
-
That was a 10 second problem.
-
So promise me.
-
You are going to do
the homework and stuff.
-
You have two or three like that.
-
If you see this on
the midterm, are you
-
going to remember the procedure,
the idea of the problem?
-
OK.
-
I'm going to also think
of writing a sample.
-
I promised Stacy I'm
going to do that.
-
And I did not forget.
-
It's going to happen.
-
After spring break, you're
going to get a review
-
sheet for the midterm.
-
I promised you a sample, right?
-
OK.
-
-
Shall I do more or not?
-
Yes?
-
You know what I'm
afraid of, really?
-
I think you will be able to do
fine with most of the problems
-
you have here.
-
I'm more worried about
geometric representations
-
in 3D of quadrics that
you guys became familiar
-
with only now,
only this semester.
-
And you have a grasp of them.
-
You've seen them.
-
But you're still not
very friendly with them,
-
and you don't
quite like to draw.
-
So let's see if we can learn
how to draw one of them together
-
and see if it's a big
deal or not because it's
-
pretty as a picture.
-
And when we set it
up as an integral,
-
it should be done wisely.
-
It shouldn't be hard.
-
-
We have to do a good job
from the moment we draw.
-
And if we don't do that,
we don't have much chance.
-
The problem is going to
change the data a little bit
-
to numbers that I like.
-
29.
-
-
You have a solid.
-
And I say solid gold, 24 k.
-
I don't know what.
-
That is between two paraboloids.
-
And those paraboloids
are given, and I'd
-
like you to tell me
what they look like.
-
One paraboloid is y-- no.
-
-
Yeah.
-
One paraboloid is
y-- I'll change it.
-
z.
-
So I can change your
problem, and then you
-
will figure it out by yourself.
-
z equals x squared
plus y squared.
-
They give you y equals x
squared plus d squared.
-
So you have to change
completely the configuration
-
of your frame.
-
And then z equals 8 minus
x squared minus y squared.
-
I'm I'm changing problem 29,
but it's practically the same.
-
Find the volume of the solid
enclosed by the two paraboloids
-
and write down the answer.
-
-
Find the volume of
the solid enclosed
-
by the two paraboloids.
-
You go, oh, my god.
-
How am I going to do that?
-
STUDENT: Draw the pictures.
-
DR. MAGDALENA TODA:
Draw the pictures.
-
Very good.
-
So he's teaching
my sensing to me
-
and says, OK, go ahead
and draw the picture.
-
Don't be lazy, because
if you don't, it's
-
never going to happen.
-
You're never going
to see the domain
-
if you don't draw the pictures.
-
So the first one will
be the shell of the egg.
-
Easter is coming.
-
So that's something
like the shell.
-
It's a terrible shell,
a paraboloid, circular
-
paraboloid.
-
And that is called z equals
x squared plus y squared.
-
-
OK.
-
-
This guy keeps going.
-
But there will be
another paraboloid
-
that has the shape of exactly
the same thing upside down.
-
STUDENT: Where's 8?
-
DR. MAGDALENA TODA: Where is 8?
-
The 8 is far away.
-
STUDENT: It's on--
-
DR. MAGDALENA TODA: I'll try.
-
-
STUDENT: Did they tell you
that a had to be positive?
-
DR. MAGDALENA TODA: Huh?
-
STUDENT: Did they tell
you a had to be positive?
-
DR. MAGDALENA TODA: Which a?
-
STUDENT: That a or whatever.
-
DR. MAGDALENA TODA: 8.
-
STUDENT: Oh, 8.
-
DR. MAGDALENA TODA: 8.
-
STUDENT: Oh, that's
why I'm confused.
-
DR. MAGDALENA TODA:
How do I know it's 8?
-
Because when I put
x equals 7 equals 0,
-
I get z equals 8
for this paraboloid.
-
This is the red paraboloid.
-
The problem-- my
question is, OK, it's
-
like it is two
eggshells that are
-
connecting, exactly this egg.
-
But the bound-- the--
how do you call that?
-
Boundary, the thing where
they glue it together.
-
What is the equation
of this circle?
-
This is the question.
-
Where do they intersect?
-
How do you find out where
two surfaces intersect?
-
STUDENT: [INAUDIBLE]
-
DR. MAGDALENA TODA:
Solve a system.
-
Make a system of two equations
and solve the system.
-
You have to intersect them.
-
So whoever x, y, z will be, they
have to satisfy both equations.
-
Oh, my god.
-
So we have to look for the
solutions of both equations
-
at the same time, which
means that I'm going
-
to say these are equal, right?
-
Let's write that down.
-
x squared plus y
squared equals 8 minus x
-
squared minus y squared.
-
Then z is whatever.
-
What is this equation?
-
We'll find out who
z is in a second.
-
-
z has to be x squared
plus y squared.
-
If we find out who the sum
of the squares will be,
-
we'll find out the altitude z.
-
z equals what number?
-
This is the whole idea.
-
So x squared.
-
I move everything to
the left hand side.
-
So I have 2x squared
plus 2y squared equals 8.
-
-
And then I have z equals
x squared plus y squared.
-
And then that's if and only
if x squared plus y squared
-
equals 4.
-
STUDENT: Then z equals 4.
-
DR. MAGDALENA TODA:
So z equals 4.
-
So z equals 4 is exactly what
I guessed because come on.
-
The two eggshells
have to be equal.
-
So this should be in the
middle between 0 and 8.
-
So I knew it was z equals 4.
-
But I had to check
it mathematically.
-
So z equals 4, and x
squared plus y squared
-
equals 4 is the boundary.
-
Let's make it purple
because it's the same
-
as the purple equation there.
-
-
So the domain has to be the
projection of this purple--
-
it looks like a sci-fi thing.
-
You have some hologram.
-
I don't know what it is.
-
It's all in your imagination.
-
You want to know the domain
D. Could somebody tell me
-
what the domain D will be?
-
It will be those x's and y's
on the floor with the quality
-
that x squared plus y squared
will be between 0 and--
-
STUDENT: 4
-
DR. MAGDALENA TODA: --4.
-
So I can do everything
in polar coordinates.
-
This is the same thing as
saying rho, theta-- r, theta.
-
Not rho.
-
Rho is Greek.
-
It's all Greek to me.
-
So rho is sometimes
used by people
-
for the polar coordinates,
rho and theta.
-
But we use r.
-
r squared between 0 and 4.
-
You'll say, Magdalena, come on.
-
That's silly.
-
Why didn't you write
r between 0 and 2?
-
I will.
-
I will.
-
I will.
-
This is 2, right?
-
So r between 0 and 2.
-
I erase this.
-
And theta is between 0 and 2 pi.
-
And I'm done.
-
Why 0 and 2 pi?
-
Because we have the whole egg.
-
I mean, I could
cut the egg in half
-
and say 0 to pi or something,
invent a different problem.
-
But for the time
being, I'm rotating
-
a full rotation of 2 pi to
create the egg all around.
-
So finally, what is
the volume of-- suppose
-
this is like in the story
with the golden eggs.
-
They are solid gold eggs.
-
Wouldn't that be wonderful?
-
We want to know the
volume of this golden egg.
-
What's inside the solid egg, not
the shell, not just the shell
-
made of gold.
-
The whole thing is made of gold.
-
And who's coming tomorrow
to the-- sorry, guys.
-
Mathematician talking.
-
Switching from
another-- who's coming
-
tomorrow to the honors society?
-
Do you-- did you decide?
-
You have.
-
And Rachel comes.
-
Are you coming?
-
No, no, no, no.
-
Tomorrow night.
-
Tomorrow night.
-
Tomorrow.
-
What time does that--
-
STUDENT: 3:00.
-
DR. MAGDALENA
TODA: At 3 o'clock.
-
At 3 o'clock.
-
OK.
-
So if you want, I can
pay your membership.
-
And then you'll be members.
-
I saw one of the certificates.
-
It was really beautiful.
-
That one [INAUDIBLE].
-
It was really-- some
parents frame these things.
-
My parents don't care.
-
But I wish they cared.
-
So the more certificates you
get, and the older you get,
-
the nicer it is to put them,
frame them and put them
-
on the wall of
fame of the family.
-
This certificate, the KME
one, looks so much better
-
than my own diplomas, the PhD
diplomas, the math diplomas.
-
And it's huge, and it
has a golden silver seal
-
will all the stuff.
-
And it's really nice.
-
OK.
-
Now coming back to this thing.
-
-
STUDENT: Can we multiply by 2?
-
Just find the--
-
DR. MAGDALENA TODA: Exactly.
-
That's what we will do.
-
We could set up the integral
from whatever it is.
-
My one function to
another function.
-
But the simplest way
to compute the volume
-
would be to say
there are two types.
-
And set up the
integral for this one,
-
for example or the other one.
-
It doesn't matter which one.
-
It doesn't really
matter which one.
-
Which one we would prefer?
-
I don't know.
-
Maybe you like the bottom
part of the [INAUDIBLE].
-
I don't know.
-
Do you guys understand
what I'm talking about?
-
STUDENT: If we
just-- I don't know
-
where to find B. Find the
area left, like indented?
-
Because if you did it at the
bottom, the domain is zero.
-
Then you have-- wouldn't
it find the stuff that
-
was not cupped out, the edges?
-
DR. MAGDALENA TODA:
Isn't it exactly
-
the same volume up and down?
-
STUDENT: Yes.
-
DR. MAGDALENA TODA: It's
the same volume up and down.
-
So it's enough for
me to take the volume
-
of the lower part and w.
-
Can you help me set
up the lower part?
-
So I'm going to have two types.
-
Can I do that directly
in polar coordinates?
-
That's the thing.
-
1 is 1.
-
r is r.
-
r is going to be-- this is
the Jacobian r drd theta.
-
-
OK?
-
But now let me ask you, how
do we compute-- I'm sorry.
-
This is the function f of x, y.
-
-
Yeah, it's a little
bit more complicated.
-
So you have to subtract
from one the other one.
-
-
So I'm referring to the domain
as being only the planar
-
domain.
-
-
And I have first a graph
and then another graph.
-
So when I want to compute,
forget about this part.
-
I want to compute the
volume of this, the volume
-
of this egg, the inside.
-
I have to say, OK, integral over
the d of the function that's
-
on top.
-
The function that's on top
is the z equals f of x, y.
-
And the function that's
on the bottom for this egg
-
is just this.
-
So this is just
a flat altitude g
-
of x, y equals-- what is that?
-
4.
-
So I have to subtract the two
because I have first this body.
-
If this would not exist, how
would I get the purple part?
-
I would say for the function f,
the protection on the ground,
-
I have this whole body
that looks like a crayon.
-
A whole body that
looks like crayon.
-
This is the first integral.
-
I minus the cylinder
that's dotted with floating
-
points, which is this part.
-
So it's V1 minus V2.
-
V1 is the volume of the whole
body that looks like a crayon.
-
V2 is just the volume of the
cylinder under the crayon.
-
We want-- minus
V2 is exactly half
-
of the egg, the volume of the
half of the egg, give or take.
-
So is this hard?
-
It shouldn't be hard.
-
f of x, y-- can you guys
tell me who that is?
-
A minus x squared
minus y squared.
-
And who is g?
-
-
4.
-
Just the altitude, 4.
-
OK.
-
So I'm going to go
ahead and say, OK,
-
I have to integrate 2 double
integral over D. 8 minus 4
-
is 4 minus x squared
minus y squared dA.
-
dA is the area element dxdy.
-
Now switch to polar.
-
How do you switch to polar?
-
-
You can also set this
up as a triple integral.
-
And that's what I
wanted to do at first.
-
But then I realized that you
don't know triple integrals,
-
so I set it up as
a double integral.
-
For a triple integral,
you have three snakes.
-
And you integrate the
element 1, and that's
-
going to be the volume.
-
And I'll teach you in
the next two sessions.
-
2 times the double integral.
-
Who is this nice fellow?
-
Look how nice and sassy he is.
-
4 minus r squared times--
never forget the r drd theta.
-
Theta goes between 0
and 2 pi and r between--
-
STUDENT: 0 and 2.
-
DR. MAGDALENA TODA: 0 and--
-
STUDENT: 2.
-
DR. MAGDALENA TODA: 2.
-
Excellent.
-
Because when I had 4 here,
that's the radius squared.
-
So r is 2.
-
Look at this integral.
-
Is it hard?
-
Not so hard.
-
Not so hard at all.
-
So what would you
do if you were me?
-
Would you do a u substitution?
-
Do you need a u
substitution necessarily?
-
You don't need it.
-
So just say 4r minus r cubed.
-
Now what do you see again?
-
Theta is missing
from the picture.
-
Theta says, I'm out of here.
-
I don't care.
-
So you get 2 times the integral
from 0 to 2 pi of nothing--
-
well, of 1d theta, not of
nothing-- times the integral
-
from 0 to 2 of 4r
minus r cubed dr.
-
4r minus r cubed dr, the
integral from 0 to 2.
-
Good.
-
-
Who's going to help me?
-
-
I give you how
much money-- money.
-
Time shall I give
you to do this one?
-
And I need three people
to respond and get
-
the same answer.
-
So [INAUDIBLE] 2r squared
minus r to the 4 over 4
-
between 0 and 2.
-
Can you do it please?
-
STUDENT: 16 [INAUDIBLE].
-
DR. MAGDALENA TODA:
How much did you get?
-
STUDENT: 4.
-
DR. MAGDALENA TODA:
How much did you get?
-
STUDENT: For just this one?
-
DR. MAGDALENA
TODA: For all this.
-
-
STUDENT: 4.
-
-
DR. MAGDALENA TODA:
Yes, it is, right?
-
Are you with me?
-
You have 2r squared
when you integrate
-
minus r to the 4 over
4 between 0 and 2.
-
That means 2 times 4 minus 16/4.
-
8 minus 4 is 4.
-
So with 4 for this guy, 2 pi
for this guy, and one 2 outside,
-
you have 16 pi.
-
And that was-- I remember
it as if it was yesterday.
-
That was on a final
two or three years ago.
-
OK.
-
So you've seen many
of these problems now.
-
It shouldn't be complicated
to start your homework.
-
Go ahead.
-
If you want, go ahead and
start with the problems
-
that we did today.
-
And when you see numbers
changed or something,
-
go ahead and work the
problem the same way.
-
Make sure you understood it.
-
I'm going to do more.
-
Is this useful for you?
-
I mean-- OK.
-
So you agree that
every now and then,
-
we do homework in the classroom?
-
Homework like problems
in the classroom.
-
In the homework, you
may have different data,
-
but it's the same
type of problem.
-
OK.
-
-
I'm going to remind you
of some Calc 2 notions
-
because today I will
cover the surface area.
-
STUDENT: Dr. Toda?
-
DR. MAGDALENA TODA: Yes, sir?
-
STUDENT: I have a question
on the last problem.
-
DR. MAGDALENA TODA: Yes, sir?
-
STUDENT: If we had seen
something like that on the exam
-
and had done it using the fact
that it's a solid revolution--
-
DR. MAGDALENA TODA:
Yeah, you can do that.
-
There are at least four
methods to do this problem.
-
One would be with
triple integral.
-
One would be with
a double integral
-
of a function on top
minus the function below.
-
One would be with solid of
revolution like in Calc 2,
-
where your axis is the z axis.
-
I don't care how you
solve the problem.
-
Again, if I were
the CEO of a company
-
or the boss of a
firm or something,
-
I would care for my employees to
be solving problems the fastest
-
possible way.
-
As long as the
answer is correct,
-
I don't care how you do it.
-
STUDENT: Thank you, Doctor.
-
DR. MAGDALENA TODA: So go ahead.
-
All right.
-
-
Oh, and by the way, I want to
give you another example where
-
the students were able
to very beautifully cheat
-
and get the right answer.
-
That was funny.
-
But that is again
a Calc 3 problem
-
in an elementary way
that can be solved
-
with the notions you have from
K-12, if you mastered them
-
[INAUDIBLE].
-
So you are given x
plus y plus z equals 1.
-
Before I do the
surface integral--
-
I could do the surface
integral for such a problem.
-
This is a plane that intersects
the coordinate planes
-
and forms a
tetrahedron with them.
-
-
Find the volume of
that tetrahedron.
-
-
Now I say, with Calc 3,
because the course coordinator
-
several years ago did not
specify with what you learned.
-
Set up a double integral
or set up-- he simply
-
said, find the volume.
-
So the students-- what's
the simplest way to do it?
-
STUDENT: That's
just half a cube.
-
DR. MAGDALENA TODA:
Just draw the thingy.
-
And they were smart.
-
They knew how to draw it.
-
The knew what the vertices were.
-
The plane looks like this.
-
If you shade it, you see
that it's x plus y plus z.
-
And I'm going to try
and write with my hands.
-
It's very hard.
-
But it comes from 0, 0, 1 point.
-
This is the 0, 0, 1.
-
And it comes like that.
-
And it hits the floor over here.
-
And these points are 1,
0, 0; 0, 1, 0; and 0, 0,
-
1 on the vertices
of a tetrahedron,
-
including the origin.
-
How do I know those are
exactly the vertices
-
of the tetrahedron?
-
Because they verify x
plus y plus z equals 1.
-
As long as the point
verifies the equation,
-
it is in the plane.
-
For example, another point
that's not in the picture
-
would be 1/3 plus 1/3 plus 1/3.
-
1/3 and 1/3 is 1/3.
-
Anything that verifies the
equation is in the plane.
-
So the tetrahedron has a name.
-
It's called-- let's call
this A, B, C, and O. OABC.
-
It's a tetrahedron.
-
It's a pyramid.
-
So how does the smart
student who was not given
-
a specific method solve that?
-
They did that on the final.
-
I'm so proud of them.
-
I said, come on now.
-
The final is two
hours and a half.
-
You don't know what to do first.
-
So they said-- they
did the base multiplied
-
by the height divided by 3.
-
So you get 1 times 1.
-
So practically, divided by 2.
-
1/2.
-
You don't even have
to do the-- even
-
my son would know that this
is half of a square, a 1
-
by 1 square.
-
So it's half the area of the
base times the height, which
-
is 1, divided by 3 is 1/6.
-
And goodbye and see you later.
-
But if you wanted-- if
the author of the problem
-
would indicate, do
that with Calculus 3,
-
then that's another
story because you
-
have to realize what the domain
would be, the planar domain.
-
You practically have a surface.
-
The green-shaded
equilateral triangle
-
is your surface, which-- let's
call it c of f from surface.
-
But this would be
z equals f of x, y.
-
How do you get to that?
-
You get it from here.
-
The explicit equation
is-- [INAUDIBLE].
-
1 minus x minus y.
-
That is the surface,
the green surface.
-
And the domain--
let's draw that in.
-
Do you prefer red or purple?
-
You don't care?
-
-
OK, I'll take red.
-
Red.
-
-
Red.
-
That's the domain D. So you'll
have to set up I, integral.
-
I for an I. And volume, double
integral over D of f of x, y,
-
whatever that is, dA.
-
That's going to be-- who is D?
-
Somebody help me, OK?
-
That's not easy.
-
So to draw the domain D, I have
to have a little bit of skill,
-
if I don't have any skill, I
don't belong in this class.
-
What do I have to draw?
-
Guys, tell me what to do.
-
0, x, and y.
-
To draw z, 0, z equals 0 gives
me x plus y equals 1, right?
-
So this is the floor.
-
Guys, this is the floor.
-
So why don't I shade it?
-
Because I'm not sure
which one I want.
-
Do I want vertical strips
or horizontal strips?
-
You're the boss.
-
You tell me what I want.
-
So do you want vertical strips?
-
-
Let's draw vertical strips.
-
So how do I
represent this domain
-
from the vertical strips?
-
x is between 0 and 1.
-
These are fixed
variable values of x
-
between fixed values 0 and 1.
-
For any such blue choice
of a point, I have a strip,
-
a vertical strip that goes
from y equals 0 down to--
-
STUDENT: 1 minus x.
-
DR. MAGDALENA TODA:
--1 minus x up.
-
Excellent, excellent.
-
This is exactly-- Roberto, you
were the one who said that?
-
OK.
-
So this is the domain.
-
So how do we write it down?
-
0 to 1.
-
0 to 1 minus x.
-
That is what I want to write.
-
No polar coordinates.
-
Goodbye.
-
There is no problem.
-
This is all a typical
Cartesian problem.
-
-
f-- f.
-
f is 1 minus x minus
y, thank you very much.
-
This is f dydx.
-
-
Homework, get 1/6.
-
-
So trying to do
that and get a 1/6.
-
And of course in the
exam-- oh, in the exam,
-
you will cheat big time, right?
-
What would you do?
-
You would set it up and forget
about computing it, integrating
-
one at a time, doing this.
-
And you would put equals 1/6.
-
Thank you very much.
-
Right?
-
Can I check that you
didn't do the work?
-
No.
-
You trapped me.
-
You got me.
-
I have no-- I mean, I need
to say, is this correct?
-
Yes.
-
Is the answer correct?
-
Yes.
-
Do they get full credit?
-
Yes.
-
So it's a sneaky problem.
-
OK.
-
Now finally, let's plunge
into 12.4, which is-- can you
-
remember this problem for 12.4?
-
I want to draw this again.
-
So I'll try not to
erase the picture.
-
I'll erase all the
data I have here.
-
And I'll keep the future because
I don't want to draw it again.
-
-
When we were small-- I
mean small in Calc 1 and 2,
-
they gave us a function
y equals f of x.
-
That is smooth, at least C1.
-
C1 means differentiable, and
the derivative is continuous.
-
-
And we said, OK, between
x equals a and x equals b,
-
I want you-- you, any
student-- to compute
-
the length of the arch.
-
Length of the arch.
-
And how did we do
that in Calc 2?
-
I have colleagues who
drive me crazy by refusing
-
to teach that in Calc 2.
-
Well, I disagree.
-
Of course, I can teach
it only in Calc 3,
-
and I can do it with
parametrization, which we did,
-
and then come back to the case
you have, y equals f of x,
-
and get the formula.
-
But it should be taught at
both levels, in both courses.
-
So when you have a
general parametrization
-
rt equals x of ty
of t [INAUDIBLE],
-
this is a parametrized
curve that's in C1, in time.
-
What is the length of the
arch between time t0 and time
-
t1 [INAUDIBLE]?
-
-
The integral from t0 to t1 or
the speed because the space
-
is the integral
of speed in time.
-
-
So in terms of speed,
remember that we
-
put square root of x prime of
t squared plus y prime of t
-
squared dt.
-
Why is that?
-
Somebody tell me.
-
That was the speed.
-
That was the magnitude
of the velocity vector.
-
And we've done that, and we
discovered that in Calculus 3.
-
In Calculus 2, they
taught this for what case?
-
The case when x is t--
say it again, I will now.
-
The case when x is
t, and y is f of t,
-
which is f of x--
and in that case,
-
as I told you before,
the length will
-
be the integral from A to B.
Whatever, it's the same thing.
-
A to B.
-
Square root-- since x
is t, x prime of t is 1.
-
So you get 1 plus-- y is just f.
-
y is f.
-
So you have f prime
of x squared dx.
-
So the length of this arch--
let me draw the arch in green,
-
so it's beautiful.
-
The length of this green
arch will be the length of r.
-
The integral from A to B square
root of 1 plus f prime 1x
-
squared dx.
-
Now there is a beautiful,
beautiful generalization
-
of that for-- generalization
for extension gives you
-
the surface area of a graph z
equals f of x, y over domain D.
-
Say what?
-
OK, it's exactly the
same formula generalized.
-
And I would like you to guess.
-
So I'd like you to
experimentally get
-
to the formula.
-
It can be proved.
-
It can be proved by taking
the equivalence of some sort
-
of Riemann summation
and passing to the limit
-
and get the formula.
-
But I would like you
to imagine you have--
-
so you have z equals f of x, y.
-
That projects exactly over
D. The area of the surface--
-
let's call it A of s.
-
-
The area of the
surface will be--
-
what do you think it will be?
-
You are smart people.
-
It will be double integral
instead of one integral
-
over-- what do you think?
-
Over the domain.
-
-
What's the simplest
way to generalize this
-
through probably [INAUDIBLE]?
-
Another square root.
-
-
We don't have just one
derivative, f prime of x.
-
We are going to have two
derivatives, f sub x and f sub
-
y.
-
So what do you think the
simplest generalization
-
will look like?
-
STUDENT: 1 plus [INAUDIBLE].
-
DR. MAGDALENA TODA: 1 plus
f sub x squared plus f sub y
-
squared dx.
-
That's it.
-
So you say, oh, I'm a genius.
-
I discovered it.
-
Yes, you are.
-
I mean, in a sense that-- no.
-
In the sense that we
all have that kind
-
of mathematical intuition,
creativity that you come up
-
with something.
-
And you say, OK, can I verify?
-
Can I prove it?
-
Yes.
-
Can you discover
things on your own?
-
Yes, you can.
-
Actually, that's how all
the mathematical minds came.
-
They came up to it
with a conjecture based
-
on some prior experiences, some
prior observations and said,
-
I think it's going
to look like that.
-
I bet you like 90% that it's
going to look like that.
-
But then it took them
time to prove it.
-
But they were convinced that
this is what it's going to be.
-
OK.
-
So if you want the area
of the patch of a surface,
-
that's going to be 4.1, and
that's page-- god knows.
-
Wait a second.
-
Wait.
-
Bare with me.
-
It starts at page 951,
and it ends at page 957.
-
It's only seven pages, OK?
-
So it's not hard.
-
You have several examples.
-
I'm going to work
on an example that
-
is straight out of the book.
-
And guess what?
-
You see, that's why I like
this problem, because it's
-
in-- example one is exactly the
one that I came up with today
-
and says, find the
same tetrahedron thing.
-
Find the surface area of
the portion of the plane
-
x plus y plus z equals
1, which was that, which
-
lies in the first octant
where-- what does it mean,
-
first octant?
-
It means that x is
positive. y is positive.
-
z is positive for z.
-
-
OK.
-
Is this hard?
-
I don't know.
-
Let's find out.
-
-
So if we were to apply this
formula, how would we do that?
-
Is it hard?
-
I don't know.
-
We have to recollect
who everybody
-
is from scratch, one at a time.
-
-
Hmm?
-
STUDENT: Could we just
use our K-12 knowledge?
-
DR. MAGDALENA TODA: Well,
you can do that very well.
-
But let's do it
first-- you're sneaky.
-
Let's do it first as Calc 3.
-
And then let's see who comes
up with the fastest solution
-
in terms of surface area.
-
By the way, this individual--
this whole fat, sausage
-
kind of thing is ds.
-
This expression is called
the surface element.
-
Make a distinction
between dA, which is
-
called area element in plane.
-
-
ds is the surface element on the
surface, on the surface on top.
-
So practically, guys, you have
some [? healy ?] part, which
-
projects on a domain in plane.
-
The dA is the infinite
decimal area of this thingy.
-
And ds is the infinite
decimal area of that.
-
What do you mean by that?
-
OK.
-
Imagine this grid of pixels
that becomes smaller and smaller
-
and smaller.
-
OK?
-
Take one pixel already and
make it infinitesimally small.
-
That's going to be
da dxdy, dx times dy.
-
What is the corresponding
pixel on the round surface?
-
I don't know.
-
It's still going to
be given by two lines,
-
and two lines form a
curvilinear domain.
-
And that curvilinear tiny-- do
you see how small it is that?
-
I bet the video cannot see it.
-
But you can see it.
-
So this tiny infinitesimally
small element
-
on the surface-- this is ds.
-
This is ds.
-
OK?
-
So if it were between a plane
and a tiny square, dxdy dA
-
and the ds here, it would
be easy between a plane
-
and a floor because
you can do some trick,
-
like a projection
with cosine and stuff.
-
But in general,
it's not so easy,
-
because you can have
a round patch that's
-
sitting above a domain.
-
And it's just-- you
have to do integration.
-
You have no other choice.
-
Let's compute it both ways.
-
Let's see.
-
A of s will be integral over
domain D. What in the world
-
was the domain D?
-
The domain D was the
domain on the floor.
-
And you told me what that
is, but I forgot, guys.
-
x is between 0 and 1.
-
Did you say so?
-
And y was between what and what?
-
Can you remind me?
-
STUDENT: [INAUDIBLE]
-
DR. MAGDALENA TODA:
Between 0 and--
-
STUDENT: 1 minus x.
-
DR. MAGDALENA TODA:
1 minus x, excellent.
-
So this is the
meaning of domain D.
-
And the square root
of-- who is f of x, y?
-
It's 1 minus x minus what?
-
Oh, right.
-
So you guys have to help
me compute this animal.
-
f sub x is negative 1.
-
Attention, please.
-
f sub y is negative 1.
-
OK.
-
So I have to say 1 plus negative
1 squared plus negative 1
-
squared dA.
-
Gosh, I'm lucky.
-
Look.
-
I mean, I'm not
just lucky, but that
-
has to be-- it has to
be something beautiful
-
because otherwise the
elementary formula will not
-
be so beautiful.
-
This is root 3, and
it brings it back.
-
Root 3 pulls out
of the whole thing.
-
So you have root 3.
-
What is double integral--
OK, let's compute.
-
So first you go dy and dx.
-
x, again, you gave
it to me, guys.
-
0 to 1.
-
y between 0 and 1 minus x.
-
Great.
-
We are almost there.
-
We are almost there.
-
I just need your
help a little bit.
-
The square root of 3 goes out.
-
The integral from 0 to 1.
-
What is the integral of 1dy?
-
It's y, y between 1 minus x
on top and 0 on the bottom.
-
That means 1 minus x.
-
If I make a mistake, just shout.
-
dx.
-
The square root of 3 times
the integral of 1 minus x.
-
STUDENT: x minus
the square root.
-
DR. MAGDALENA TODA: x
minus the square root of 2.
-
Let me write it separately
because I should do that fast,
-
right?
-
Between 0 and 1.
-
What is that?
-
-
1/2.
-
That's a piece of cake.
-
This is 1/2.
-
So 1/2 is this thing.
-
And root 3 over 2.
-
And now Alex says,
congratulations
-
on your root 3
over 2, but I could
-
have told you that much faster.
-
So the question
is, how could Alex
-
have shown us this root
3 over 2 much faster?
-
STUDENT: Well, it's
just a triangle.
-
DR. MAGDALENA TODA:
It's just a triangle.
-
It's not just a triangle.
-
It's a beautiful triangle
that's an equilateral triangle.
-
And in school, they used
to teach more trigonometry.
-
And they don't.
-
And if I had the
choice-- I'm not
-
involved in the K-12 curriculum
standards for any state.
-
But if I had the choice, I
would say, teach the kids
-
a little bit more
geometry in school
-
because they don't know
anything in terms of geometry.
-
So there were
triumphs in the past,
-
and your parents may
know those better.
-
But If somebody gave you
an equilateral triangle
-
of a certain side, you
would be able to tell them,
-
I know your area.
-
I know the area.
-
I know the area being l squared,
the square root of 3 over 4.
-
Your parents may know that.
-
Aaron, ask your dad.
-
He will know.
-
But we don't teach
that in school anymore.
-
The smart kids do this
by themselves how?
-
Can you show me how?
-
They draw the
perpendicular bisector.
-
And there is a
theorem actually--
-
but we never prove
that in school--
-
that if we draw that
perpendicular bisector,
-
then the two triangles
are congruent.
-
And as a consequence,
well, that is l/2, l/2.
-
OK?
-
So if you draw just
the perpendicular,
-
you can prove it using some
congruence of triangles
-
that what you get here
is also the median.
-
So it's going to keep
right in the middle
-
of the opposite side.
-
So you l/2, l/2.
-
OK.
-
That's what I wanted to say.
-
And then using the
Pythagorean theorem,
-
you're going to get the height.
-
So the height will be the square
root of l squared minus l/2
-
squared, which is the
square root of l squared
-
minus l squared over 4, which
is the square root of 3l squared
-
over 4, which simplified
will be l root 3 over 2.
-
l root 3 over 2 is
exactly the height.
-
And then the area will be
height times the base over 2
-
for any triangle.
-
So I have the height times
the base over 2, which
-
is root 3l squared over 4.
-
So many people when
they were young
-
had to learn it in
seventh grade by heart.
-
Now in our case, it
should be a piece of cake.
-
Why?
-
Because we know who l is.
-
l is going to be the hypotenuse.
-
We have here a 1 and
a 1, a 1 and a 1.
-
So this is going to be the
hypotenuse, square root of 2.
-
So if I apply this
formula, which
-
is the area of the
equilateral triangle,
-
that says root 2 squared root
3 over 4 equals 2 root 3 over 4
-
equals root 3 over 2.
-
-
So can you do that?
-
Are you allowed to do that?
-
Well, we never formulated
it actually saying
-
compute the surface of
this patch of a plane using
-
the surface integral.
-
We didn't say that.
-
We said, compute it,
period We didn't care how.
-
If you can do it
by another method,
-
whether to stick to that
method, elementary method
-
or to just check
your work and say,
-
is it really a square
root of 3 over 2?
-
You are allowed to do that.
-
Questions?
-
STUDENT: So would the
length be square root
-
of 2 squared, which is 2.
-
2 divided by 4 is [INAUDIBLE]
square root of 3 over 2.
-
I'm just talking-- oh, yeah.
-
DR. MAGDALENA TODA: You are
just repeating what I have.
-
So the answer i got
like this is elementary.
-
And the answer I got
like this is with Calc 3.
-
It's the same answer, which
gives me the reassurance
-
I wasn't speaking nonsense.
-
I did it in two different ways,
and I got the same answer.
-
Let's do one or
two more examples
-
of surface integrals, surface
areas and surface integrals.
-
It's not hard.
-
It's actually quite fun.
-
Some of them are
harder than others.
-
Let's see what we can do.
-
-
Oh, yeah.
-
I like this one very much.
-
-
I remember we gave it several
times on the final exams.
-
So let's go ahead
and do one like that
-
because you've
seen-- why don't we
-
pick the one I picked before
with the eggshells for Easter,
-
like Easter eggs?
-
What was the paraboloid I
had on top, the one on top?
-
STUDENT: 8 minus x--
-
DR. MAGDALENA TODA: 8 minus
x squared [INAUDIBLE].
-
That's what I'm going to pick.
-
And I'll say, as Easter
is coming, a word problem.
-
We want to compute the
surface of an egg that
-
is created by intersecting
the two paraboloids 8 minus x
-
squared minus y squared and
x squared plus y squared.
-
So let's see.
-
-
No.
-
Not y, Magdalena.
-
-
Intersect, make
the egg intersect.
-
Create the eggshells.
-
-
Shells.
-
Compute the area.
-
-
And you say, wait a minute.
-
The two eggshells were equal.
-
Yes, I know.
-
I know that the two
eggshells were equal.
-
But they don't look
equal in my picture.
-
I'll try better.
-
-
Assume they are parabolas.
-
-
Assume this was z equals 4.
-
This was 8 minus x
squared minus y squared.
-
This was x squared
plus y squared.
-
How do we compute-- just
like Matthew observed, 8
-
for the volume.
-
I only need half of the
8 multiplied by the 2.
-
The same thing.
-
I'm going to take one of
the two shells, this one.
-
And the surface of the egg will
be twice times the surface S1.
-
All I have to
compute is S1, right?
-
It shouldn't be a big problem.
-
I mean, what do I
need for that S1?
-
I only need the shadow of
it and the expression of it.
-
The shadow of it and the--
the shadow of it is this.
-
The shadow of this is this.
-
And the expression-- hmm.
-
It shouldn't be hard.
-
-
So I'm going to-- I'm
going to start asking
-
you to tell me what to write.
-
-
What?
-
STUDENT: Square root of 1 plus--
-
DR. MAGDALENA TODA: No.
-
First I will write
the definition.
-
Double integral over D,
square root of, as you said--
-
say it again.
-
STUDENT: 1 plus f
of x squared plus f
-
of y squared [INAUDIBLE] dA.
-
-
DR. MAGDALENA TODA: All right.
-
So this is ds, and I'm
integrating over the domain.
-
Should this be hard?
-
No, it shouldn't be hard.
-
But I'm going to get
something a little bit ugly.
-
And it doesn't matter, because
we will do it with no problem.
-
I'm going to say, integral
over-- now the domain
-
D-- I know what it is
because the domain D will
-
be given by x squared
plus y squared less than
-
or equal to 4.
-
So I would know how to
deal with that later on.
-
Now what scares me off
a little bit-- and look
-
what's going to happen.
-
When I compute f sub x and f sub
y, those will be really easy.
-
But when I plug
everything in here,
-
it's going to be
a little bit hard.
-
Never mind, I'm
going to have to have
-
to battle the problem
with polar coordinates.
-
That's why polar coordinates
exist, to help us.
-
So f sub x is minus 2x, right?
-
f sub y is minus 2y.
-
-
OK.
-
So what am I going
to write over here?
-
Minus 2x squared plus
minus 2y squared dx.
-
I don't have much room.
-
But that would mean dxdy.
-
Am I happy with that?
-
No.
-
I'm not happy with
it, because here it's
-
going to be x squared plus
y squared between 0 and 4.
-
-
And I'm not happy with it,
because it looks like a mess.
-
And I have to find this area
integral with a simple method,
-
something nicer.
-
Now the question is,
does my elementary math
-
help me find the
area of the egg?
-
Unfortunately, no.
-
So from this point on, it's
goodbye elementary geometry.
-
STUDENT: Unless you
know the radius.
-
DR. MAGDALENA TODA: But they
are not spheres or anything.
-
I can approximate the
eggs with spheres,
-
but I cannot do anything with
those paraboloids [INAUDIBLE].
-
STUDENT: I know the
function of the top.
-
DR. MAGDALENA TODA:
Yeah, yeah, yeah.
-
You can.
-
STUDENT: [INAUDIBLE]
the integration f prime.
-
DR. MAGDALENA TODA: But
it's still integration.
-
So can I pretend like I'm a
smart sixth grader, and I can--
-
how can I measure that if I'm
in sixth grade or seventh grade?
-
With some sort of graphic paper,
do some sort of approximation
-
of the area of the egg.
-
It's a school project that's
not worth anything because I
-
think not even at a science
fair, could I do it.
-
STUDENT: Unless--
in the same radius,
-
I can draw the sphere in.
-
Then if I apply the
distance between the sphere
-
and the [INAUDIBLE] the
distance between [INAUDIBLE]
-
and take it all from there.
-
But then the function
actually will look easier
-
because it will go from the
y axis up to the A axis,
-
and they meet each other.
-
So I took up the
area and took up
-
the other area to [INAUDIBLE].
-
-
DR. MAGDALENA TODA: Yeah.
-
Well, wouldn't that
surface of the egg still
-
be an approximation
of the actual answer?
-
Anyway, let's come
back to the egg.
-
The egg, the egg.
-
The egg is [INAUDIBLE].
-
It's nice.
-
1 plus 4 x squared
plus y squared.
-
Look at the beauty of the
symmetry of polynomials.
-
x squared plus y squared says,
I'm a symmetric polynomial.
-
You're my friend
because I'm r squared,
-
and I know what I'm going to do.
-
So how do we compute?
-
What kind of integral
do we need to compute?
-
So S1 will be the integral of
integral of the square root
-
of 1 plus 4r squared.
-
Don't forget the dA
contains the Jacobian.
-
So don't write drd theta.
-
I had a student who wrote that.
-
That is worth
exactly zero points.
-
So say, times r.
-
r between-- oh, my god,
the poor egg-- 0 to 2.
-
And theta between 0 to 2 pi.
-
And come on.
-
We've done that in Calc 2.
-
I mean, it's not so hard.
-
So u substitution.
-
u is 4r squared plus 1.
-
That's our only hope.
-
We have no other hope.
-
du is going to be 8rdr.
-
And rdr is a married couple.
-
They stick together.
-
Where is the purple?
-
The purple is here.
-
rdr, rdr.
-
rdr is du/8.
-
-
This fellow's name is u.
-
He is u.
-
He is not u, but he's like u.
-
OK, not necessary.
-
OK.
-
So you go 2 pi-- because
there is no theta.
-
So no theta means-- let me
write it one more time for you.
-
The integral from
0 to 2 pi 1d theta.
-
And he goes out and has fun.
-
This is 2 pi.
-
But then all you have left
inside is the integral of u.
-
Square root of u times
1/8 du, close the bracket,
-
where u is between 1 and 17.
-
Isn't that beautiful?
-
That's 17.
-
So you have 2 squared
times 416 plus 117.
-
But believe me that from this
viewpoint, from this point on,
-
it's not really hard.
-
It just looks like the
surface of that egg
-
is-- whenever it was produced,
in what factory, in whatever
-
country is the toy factory, they
must have done this area stage.
-
So you have 2 pi.
-
1/8 comes out, whether
he wants out or not.
-
Integral of square root of u.
-
Do you like that?
-
I don't.
-
You have--
-
STUDENT: 2/3.
-
DR. MAGDALENA TODA:
2/3 u to the 3/2
-
between-- down is u equals 1.
-
Up is u equals 17.
-
So I was asked,
because we've done
-
this in the past
reviews for the finals--
-
and several finals
are like that.
-
My students asked me, what
do I do in such a case?
-
Nothing.
-
I mean, you do nothing.
-
You just plug it in
and leave it as is.
-
So you have-- to simplify
your life a little bit, what
-
you can do is 2, 2, and 8.
-
What is 2 times 2?
-
4.
-
Divided by 8-- so you
have pi/6 overall.
-
-
pi/6 times 17 to
the 3/2 and minus 1.
-
-
One of my students, after he
got such an answer last time
-
we did the review, he
said, I don't like it.
-
I want to write this as
square root of 17 cubed.
-
You can write it
whatever you want.
-
It can be-- it
has to be correct.
-
I don't care how you write it.
-
What if you mess up?
-
You say, well, this
woman is killing me
-
with her algebra over here.
-
OK.
-
If you understood--
suppose that you
-
are taking the final right now.
-
You drew the
picture beautifully.
-
You remember the problem.
-
You remember the formula.
-
You write it down.
-
You wrote it down.
-
You got to this point.
-
At this point, you already
have 50% of the problem.
-
Yup.
-
And then from this point on,
you do the polar coordinates,
-
and you still get another 25%.
-
You messed it up.
-
You lose some partial credit.
-
But everything you
write correctly
-
earns and earns
and earns points.
-
OK?
-
So don't freak out
thinking, I'm going
-
to mess up my algebra for sure.
-
If you do, it doesn't matter,
because even if this would
-
be a multiple choice--
some problems will
-
be show work completely,
and some problems
-
may be multiple
choice questions.
-
Even if this is going
to be a multiple choice,
-
I will still go over the entire
computation for everybody
-
and give partial credit.
-
This is my policy.
-
We are allowed to choose
our policies as instructors.
-
So you earn partial credit
for everything you write down.
-
OK.
-
Was this hard?
-
It's one of the harder
problems in the book.
-
It is he similar to
example number-- well,
-
this is exactly like
example 2 in the section.
-
-
So we did these two
examples from the section.
-
And I want to give you one
more piece of information
-
that I saw, that unfortunately
my colleagues don't teach that.
-
And it sort of bothers me.
-
I wish they did.
-
-
Once upon a time,
a long time ago,
-
I taught you a little bit
more about the parametrization
-
of a surface.
-
And I want to give you yet
another formula, not just
-
this one but one more.
-
So what if you have a
generalized surface that
-
is parametrized, meaning
that your surface is not
-
given as explicitly
z equals f of x, y?
-
That's the lucky case.
-
That's a graph.
-
We call that a graph,
z equals f of x and y.
-
And we call ourselves lucky.
-
But life is not always so easy.
-
Sometimes all you can get
is a parametrization r
-
of v, v for a surface.
-
And from that, you
have to deal with that.
-
So suppose somebody says,
I don't give you f of x, y,
-
although locally every
surface looks like the graph.
-
But a surface doesn't have
to be a graph in general.
-
Locally, it does look like
a graph on a small length.
-
But in general, it's
given by r, v, v equals--
-
and that was what?
-
I gave you something like x of
u, v I plus y of u, v J plus z
-
of u, v-- let's not put
things in alphabetical order.
-
-
z of u, v J and K.
-
And we said that
we have a point.
-
P is our coordinate u0, v0.
-
And we said we
look at that point,
-
and we try to draw the partials.
-
What are the partials from
a geometric viewpoint?
-
Well, if I want to
write the partials,
-
they would be various.
-
It's going to be the vector
x sub u, y sub u, z sub
-
u, and the vector x sub v, y
sub v, z sub v, two vectors.
-
Do you remember when I
drew them, what they were?
-
-
We said the following.
-
We said, let's assume
v will be a constant.
-
-
So we say, v is a constant.
-
And then v equals v0.
-
And then you have P of u0, v0.
-
-
And then we have another,
and we have u equals u0.
-
-
This guy is going to
be who of the two guys?
-
r sub u.
-
When we measure out
the point P, r sub u
-
is this guy, who is tangent
to the line r of u, v zero.
-
-
Does it look tangent?
-
I hope it looks tangent.
-
And this guy will be r of
u-- because u0 means what?
-
u0 and v. So who
is free to move?
-
v. So this guy, this r sub
v-- they are both tangents.
-
So do you have a surface?
-
This is the surface.
-
This is the surface.
-
And these two horns or
whatever they are-- those
-
are the tangents r sub u, r
sub v, the two tangent vectors,
-
the partial velocities.
-
And I told you before, they
form the tangent plane.
-
They are partial velocities.
-
They are both tangent to
the surface at that point.
-
They form a basis.
-
They are linearly independent.
-
Always?
-
No.
-
But we assume that r sub u
and r sub v are non-zero,
-
and they are not co-linear.
-
How do I write that?
-
They are not parallel.
-
So guys, what does it mean?
-
It means-- we talked
about this before.
-
The velocities cannot be 0.
-
And r sub u, r sub v
cannot be parallel,
-
because if they are parallel,
there is no area element.
-
There is no tangent
plane between them.
-
What they form is
the area element.
-
So what do you think the
area element will look like?
-
It's a magic thing.
-
The surface element
actually will
-
be exactly the area between ru
and rv times the u derivative.
-
Say it again, Magdalena.
-
What the heck is the area
between the vectors r sub
-
u, r sub v?
-
You know it better than
me because you're younger,
-
and your memory is better.
-
And you just covered
this in chapter nine.
-
When you have a vector A
and a vector B that are not
-
co-linear, what was the
area of the parallelogram
-
that they form?
-
STUDENT: The
magnitude [INAUDIBLE].
-
DR. MAGDALENA TODA:
Magnitude of--
-
STUDENT: The cross product.
-
DR. MAGDALENA TODA:
The cross product.
-
Excellent.
-
This is exactly what
I was hoping for.
-
The magnitude of the
cross product is the area.
-
So you have ds, infinitesimal
of an answer plus area, surface
-
element will be
exactly the magnitude
-
of the cross product of the
two velocity vectors, dudv.
-
dudv can also be
written dA in this case
-
because it's a flat
area on the floor.
-
It's the area of a tiny
square on the floor,
-
infinitesimally small square.
-
So remember that.
-
And you say, well, Magdalena,
you are just feeding us
-
formula after formula.
-
But we don't even know.
-
OK, this makes sense.
-
This looks like I have some
sort of tiny parallelogram,
-
and I approximate the
actual curvilinear
-
patch, curvilinear
patch on-- I'm
-
going to draw it on my hand.
-
So this is-- oh, my god.
-
My son would make fun of me.
-
So this curvilinear patch
between two curves on my hand
-
will be actually
approximated by this.
-
What is this rectangle?
-
No, it's a--
-
STUDENT: Parallelogram.
-
DR. MAGDALENA TODA:
Parallelogram.
-
Thank you so much.
-
So this is an
approximation, again.
-
So this is the area
of the parallelogram.
-
-
And that's what we defined
as being the surface element.
-
It has to do with
the tangent plane.
-
But now you're asking,
but shouldn't this
-
be the same as the formula
root of 1 plus f sub x squared
-
plus f sub y squared dxdy?
-
Yes.
-
Let's prove it.
-
Let's finally prove that
the meaning of this area
-
will provide you
with the surface
-
element the terms of x
and y, just the way you--
-
you did not prove it.
-
You discovered it.
-
Remember, guys?
-
You came up with a
formula as a conjecture.
-
You said, if we generalize
the arch length,
-
it should look like that.
-
You sort of smelled it.
-
You said, I think.
-
I feel.
-
I'm almost sure.
-
But did you prove it?
-
No.
-
So starting from the
idea of the area element
-
that I gave before,
do you remember
-
that we also had that signed
area between the dx and dy,
-
and we used the area of
the parallelogram before?
-
We also allowed it to
go oriented plus, minus.
-
OK.
-
All right.
-
So this makes more sense
than what you gave me.
-
Can I prove what you
gave me based on this
-
and show it's one
and the same thing?
-
So hopefully, yes.
-
If I have my explicit form
z equals f of x and y,
-
I should be able to
parametrize this surface.
-
How do I parametrize
this surface
-
in the simplest possible way?
-
-
x is u.
-
y is v. z is f of
u, v. And that's it.
-
Then it's r of u, v as a vector
will be angular bracket, u, v,
-
f of u, v. Now you have to
help me compute r sub u and r
-
sub v. They have to
be these blue vectors,
-
the partial velocities.
-
r sub u, r sub v.
-
Is it hard?
-
Come on.
-
It shouldn't be hard.
-
I need to change colors.
-
So can you tell
me what they are?
-
-
What's the first-- 1?
-
Good.
-
What's next?
-
0.
-
Thank you.
-
STUDENT: F sub u.
-
DR. MAGDALENA TODA: f sub u.
-
Very good.
-
f sub u or f sub x is the same
because x and u are the same.
-
So let me rewrite
it 1, 0, f sub x.
-
Now the next batch.
-
0, 1, f sub v, which
is 0, 1, f sub y.
-
0, 1, f sub y.
-
-
Now I need to cross them.
-
And I need to cross them, and
I'm too lazy because it's 2:20.
-
But I'll do it.
-
I'll do it.
-
I'll cross.
-
So with your help
and everything,
-
I'm going to get to
where I need to get.
-
-
You can start.
-
I mean, don't wait for me.
-
Try it yourselves
and see what you get.
-
And how hard do you think
it is to compute the thing?
-
STUDENT: [INAUDIBLE]
-
-
DR. MAGDALENA TODA: I
will do the normality
-
at the magnitude later.
-
r sub u, r sub v's cross product
will be I, J, K. 1, 0, f sub x,
-
0, 1, f sub y.
-
Is this hard?
-
It shouldn't be hard.
-
So I have minus f sub x, what?
-
I. I'm sorry.
-
I for an I. OK.
-
J, again minus because
I need to change.
-
When I expand along the row, I
have plus, minus, plus, minus,
-
plus, alternating.
-
So I need to have minus.
-
The determinant is f sub y times
J plus K times this fellow.
-
But that fellow is 1, is the
minor 1, for god's sakes.
-
So this is so easy.
-
I got the vector,
but I need the norm.
-
But so what?
-
Do you have it?
-
I'm there, guys.
-
I'm really there.
-
It's a piece of cake.
-
I take the components.
-
I squeeze them a little bit.
-
No.
-
I square them,
and I sum them up.
-
And I get the square
root of 1 plus-- exactly.
-
1 plus f sub x squared
plus f sub y squared d.
-
This is u and v, and this
is dxdy, which is dA.
-
This is the tiny floor square
of an infinitesimally square
-
on the floor.
-
OK?
-
And what is this again?
-
This is the area of
a tiny curvilinear
-
patch on the surface that's
projected on that tiny square
-
on the floor.
-
All right?
-
OK.
-
So Now you know why
you get what you get.
-
One the last problem
because time is up.
-
No, I'm just kidding.
-
We still have plenty of time.
-
-
This is a beautiful,
beautiful problem.
-
But I don't want to finish it.
-
I want to give you
the problem at home.
-
It's like the one
in the book, but I
-
don't want to give you
exactly the one in the book.
-
-
I want to cover
something special today.
-
-
We are all familiar with their
notion of a spiral staircase.
-
But spiral staircases
are everywhere,
-
in elegant buildings, official
buildings, palaces, theaters,
-
houses of multimillionaires
in California.
-
And even people who
are not millionaires
-
have some spiral
staircases in their houses,
-
maybe made of wood
or even marble.
-
Did you ever wonder why
the spiral staircases
-
were invented?
-
If you go to most of the
castles on the Loire Valley,
-
or many European castles
have spiral staircases.
-
Many mosques, many churches
have these spiral staircases.
-
I think it was about a few
thousand years ago that it
-
was documented
for the first time
-
that the spiral staircases
consumed the least
-
amount of materials to build.
-
-
Also what's good about them
is that for confined spaces--
-
you have something like a
cylinder tower like that--
-
that's the only shape you
can build that minimizes
-
the area of the staircase
because if you start building
-
a staircase like
ours here, it's not
-
efficient at all in
terms of construction,
-
in terms of materials.
-
So you get a struggle
at actually making
-
these stairs that are not even.
-
You know, they're not even even.
-
Each of them will have a
triangle, or what is this?
-
Not a triangle, but
more like a trapezoid.
-
And it keeps going up.
-
This comes from a
helix, obviously.
-
And we have to understand
why this happens.
-
And I will introduce the
surface called helicoid.
-
-
And the helicoid will have
the following parametrization
-
by definition.
-
u cosine v, u sine v, and v.
-
Assume u is between 0 and 1 and
assume v is between 0 and 2 pi.
-
Draw the surface.
-
-
Also find the surface area of
the patch u between 0 and 1,
-
v between 0 and pi/2.
-
-
So I go, uh oh.
-
I'm in trouble.
-
Now how in the world am I
going to do this problem?
-
It looks horrible.
-
And it looks hard.
-
And it even looks hard to draw.
-
It's not that hard.
-
It's not hard at
all, because you
-
have to think of these
extreme points, the limit
-
points of u and v and see what
they really represent for you.
-
Put your imagination
to work and say,
-
this is the frame
I'm starting with.
-
This is the x and y and
z frame with origin 0.
-
And I better draw this helicoid
because it shouldn't be hard.
-
So for u equals
0, what do I have?
-
-
I don't know.
-
It looks weird.
-
But Alex said it.
-
0, 0, v. v is my
parameter in real life.
-
So I have the whole z-axis.
-
So one edge is going to
be the z-axis itself.
-
Does it have to be
only the positive one?
-
No.
-
Who said so?
-
My problem said so,
that v only takes
-
values between 0 and 2 pi.
-
Unfortunately, I'm limiting
v between 0 and 2 pi.
-
But in general, v could
be any real number.
-
So I'll take it from
0 to 2 pi, and this
-
is going to be what I'm thinking
of, one edge of the staircase.
-
-
It's the interior age, the axis.
-
Let's see what happens
when u equals 1.
-
That's another curve
of the surface.
-
Let's see what I get.
-
Cosine v, sine v, and v. And it
looks like a friend of yours.
-
And you have to
tell me who this is.
-
If v were bt, what
is sine, cosine tt?
-
STUDENT: A sphere.
-
DR. MAGDALENA TODA: It's your--
-
STUDENT: Helicoid.
-
DR. MAGDALENA TODA: --helix
that you loved in chapter 10
-
and you made friends with.
-
And it was a curve that had
constant curvature and constant
-
portion, and it
had constant speed.
-
And the speed of
this, for example,
-
would be square root of 2,
if you have the curiosity
-
to compute it.
-
It will have square root of 2.
-
And can I draw it?
-
I better draw it,
but I don't know how.
-
-
So I have to think of drawing
this for v between 0 and 2 pi.
-
-
When I'm at 0, when I
have time v equals 0,
-
I have the point 1, 0, and 0.
-
And where am I?
-
Here.
-
1, 0, 0.
-
And from here, I start moving
on the helix and going up.
-
And see, my hand should be
on-- this is the stairs.
-
It's obviously a smooth surface.
-
This is a smooth
surface, but the stairs
-
that I was talking about
are a discretization
-
of the smooth surface.
-
I have a step, another step,
another step, another step.
-
So it's like a smooth helicoid
but discretized step functions.
-
Forget about the step functions.
-
Assume that instead of the
staircase in the church--
-
you don't want to go to church.
-
You want to go to
the water park.
-
You want to go to Six Flags.
-
You want to go to whatever,
Disney World, San Antonio,
-
somewhere.
-
This is a slide.
-
You let yourself go.
-
This is you going
down, swimming--
-
I don't know-- upside down.
-
I don't know how.
-
So this is a smooth
slide in a water park.
-
That's how you should
be imagining it.
-
And it keeps going.
-
If I start here-- if I
start here, again, look,
-
this is what I'm describing.
-
-
A helicoid.
-
My arm moved on this.
-
Again, I draw the same motion.
-
My elbow should not
do something crazy.
-
It should keep
moving on the z-axis.
-
And I perform the pi/2 motion
when the stair-- not the stair.
-
I don't know what to call it.
-
This line becomes horizontal
when v equals pi/2.
-
So for v equals pi/2, I moved
from here straight to here.
-
STUDENT: Doesn't it go around?
-
DR. MAGDALENA TODA:
It goes around.
-
But see, what I asked-- I
only asked for the patch.
-
First of all, I
said it goes around.
-
So I'll try to go around.
-
But it's hard.
-
Oh, wish me luck.
-
One, two, three.
-
I cannot go higher.
-
It goes to pi.
-
STUDENT: If it went to
2 pi, it would actually
-
wrap completely around?
-
DR. MAGDALENA TODA: It
would wrap like that.
-
STUDENT: Right above
where it started?
-
DR. MAGDALENA TODA: Exactly.
-
So if I started here, I end
up parallel to that, up.
-
But 2 pi is too high for me.
-
So I should go slowly.
-
-
I'm up after 2 pi in
the same position.
-
STUDENT: But since it's pi/2,
it's just kind of like--
-
DR. MAGDALENA TODA:
When I'm pi/2,
-
I just performed
from here to here.
-
STUDENT: So that's it's
asking you for the patch?
-
DR. MAGDALENA TODA:
And it's asking for,
-
what area does my arm from here
to here sweep at this point?
-
From this point to this point.
-
It's a smooth surface.
-
So it's generated by my motion.
-
And stop.
-
It's a root surface.
-
It's a root patch of a surface.
-
Somebody tell me how I'm going
to do this because this is not
-
with square root of 1 plus f sub
x squared plus f sub y squared.
-
That is for normal people.
-
You are not normal people.
-
They never teach this in honors.
-
In honors, we don't
cover this formula.
-
But you're honors.
-
So do I want you to finish
it at home with a calculator?
-
All I want is for you to be
able to set up the integral.
-
And I think, knowing you
better and working with you--
-
I think you have the potential
to do that without my help,
-
with all the elements
I gave you until now.
-
So the area of s-- it
will be the blue slide.
-
These are all--
when you slide down,
-
you slide down along helices.
-
You and your friends-- you're
going down along helices.
-
OK?
-
So that's what you have.
-
[INAUDIBLE] double integral
for a certain domain D.
-
Which is that domain D?
-
That domain D is u between 0
and 1 and v between 0 and pi/2
-
because that's what
I said I want here.
-
-
Of what?
-
Of magnitude of r sub u times
r sub v cross product dudv.
-
-
You need to help me
though because I don't
-
know what I'm going to do.
-
So who starts?
-
r sub u is-- I'm not doing
anything without you, I swear.
-
OK?
-
STUDENT: Cosine.
-
DR. MAGDALENA TODA: Cosine v.
-
STUDENT: Sine v.
-
DR. MAGDALENA TODA: Sine v.
-
STUDENT: And 0.
-
DR. MAGDALENA TODA: 0.
-
r sub v equals--
-
STUDENT: Negative u sine v.
-
DR. MAGDALENA TODA: Very good.
-
u cosine v. And 1, and
this goes on my nerves.
-
But what can I do?
-
Nothing.
-
OK?
-
All right.
-
So I have to compute the what?
-
STUDENT: The cross product.
-
DR. MAGDALENA TODA:
The cross product.
-
-
I, J, K, of course, right?
-
I, J, K, cosine v, sine v,
0, minus u sine-- oh, my god.
-
Where was it?
-
It's there.
-
You gave it to me.
-
u cosine v and 1.
-
Minus u sine v, u
cosine v, and 1.
-
OK.
-
I times that.
-
Sine v, I. sine v,
I. J. J has a friend.
-
Is this mine or--
cosine v times 1.
-
But I have to change the sine.
-
Are you guys with me?
-
It's really serious that I have
to think of changing the sine.
-
Minus cosine v times
J. Are you with me?
-
-
This times that
with a sign change.
-
And then plus-- what is--
well, this is not so obvious.
-
But you have so much practice.
-
Make me proud.
-
What is the minor
that multiplies K?
-
This red fellow.
-
You need to compute
it and simplify it.
-
So I don't talk too much.
-
-
u, excellent.
-
How did you do it, [INAUDIBLE]?
-
STUDENT: [INAUDIBLE].
-
DR. MAGDALENA TODA: So
you group together cosine
-
squared plus sine squared.
-
Minus, minus is a plus.
-
And you said u, it's u.
-
Good.
-
Plus u times K. Good.
-
It doesn't look so bad.
-
Now that you look at it,
it doesn't look so bad.
-
You have to set up the integral.
-
And that's going to be what?
-
The square root of
this fellow squared
-
plus that fellow squared
plus this fellow squared.
-
Let's take our time.
-
You take these three fellows,
square them, add them up,
-
and put them under
a square root.
-
Is it hard?
-
STUDENT: 1 plus u squared.
-
DR. MAGDALENA TODA:
1 plus u squared.
-
Now the thing is I
don't have a Jacobian.
-
This is dudv.
-
The Jacobian is what?
-
So this is what I have.
-
Now between the end
points, I have to think.
-
v has to be between 0 and pi/2.
-
-
And u has to be between 0 and 1.
-
-
Do you notice anything?
-
And that's exactly what
I wanted to tell you.
-
v is not inside.
-
v says, I'm independent.
-
Please leave me alone.
-
I'll go off, take a break. pi/2.
-
But then you have
integral from 0
-
to 1 square root of
1 plus u squared du.
-
I want to say a remark.
-
-
Happy or not happy, shall I be?
-
Here, you need either
the calculator,
-
which is the simplest
way to do it, just
-
compute the simple integral.
-
Integral from 0 to 1 square
root of 1 plus u squared du.
-
Or what do you have in this
book that can still help you
-
if you don't have a calculator?
-
STUDENT: [INAUDIBLE]
-
DR. MAGDALENA TODA: A table of
integration, integration table.
-
Please compute this.
-
I mean, you cannot
give me an exact value.
-
But give me an approximate
value by Thursday.
-
Is today Tuesday?
-
Yes.
-
By Thursday.
-
So please let me know how much
you got from the calculator
-
or from integration tables.
-
So we have this
result. And then I
-
would like to interpret
this result geometrically.
-
What we can say about the
helicoid that I didn't tell you
-
but I'm going to tell you
just to finish-- have you
-
been to the OMNIMAX
Science Spectrum, the one
-
in Lubbock or any other?
-
I think they are
everywhere, right?
-
I mean-- everywhere.
-
We are a large city.
-
Only in the big cities can
you come to a Science Spectrum
-
museum kind of like that.
-
Have you played
with the soap films?
-
OK.
-
Do you remember what kind
wire frames they had?
-
They had the big tub with soapy
water, with soap solution.
-
And then there were all sorts
of [INAUDIBLE] in there.
-
They had the wire with pig
rods that looked like a prism.
-
They had a cube that they wanted
you to dip into the soap tub.
-
They had a heart.
-
And there comes the
beautiful thing.
-
They had this, a
spring that they took
-
from your grandfather's bed.
-
No.
-
I don't think it
was flexible at all.
-
It was a helix made with
a rod inside, a metal rod
-
inside and attached
to the frame of that.
-
There was the metal rod and
this helix made of hard iron,
-
and they were sticking together.
-
Have you dipped this
into the soap solution?
-
And what did you get?
-
STUDENT: [INAUDIBLE]
-
DR. MAGDALENA TODA: That's
exactly what you get.
-
You can get several surfaces.
-
You can even get the one on
the outside that's unstable.
-
It broke in my case.
-
It's almost like a cylinder.
-
The one that was pretty
stable was your helicoid.
-
The helicoid is a so-called
soap film, soap film
-
or minimal surface.
-
Minimal surface.
-
So what is a minimal surface?
-
A minimal surface
is a soap film.
-
A minimal surface
is a surface that
-
tends to minimize the area
enclosed in a certain frame.
-
You take a wire that looks like
a loop, its own skew curve.
-
You dip that into
the soap solution.
-
You pull it out.
-
You get a soap film.
-
That a minimal surface.
-
So all the things
that you created
-
by taking wires and dipping
them into the soap tub
-
and pulling them out-- they
are not just called soap films.
-
They are called
minimal surfaces.
-
Somewhere on the wall
of the Science Spectrum,
-
they wrote that.
-
They didn't write much about
the theory of minimal surfaces.
-
But there are people-- there
are famous mathematicians who
-
all their life studied
just minimal surfaces, just
-
soap films.
-
They came up with the results.
-
Some of them got very
prestigious awards
-
for that kind of thing
theory for minimal surfaces.
-
And these have been known
since approximately the middle
-
of the 19th century.
-
There were several
mathematicians
-
who discovered the most
important minimal surfaces.
-
There are several that
you may be familiar with
-
and several you may
not be familiar with.
-
But another one that you may
have known is the catenoid.
-
And that's the last thing I'm
going to talk about today.
-
Have you heard of a catenary?
-
Have you ever been to St. Louis?
-
St. Louis, St. Louis.
-
The city St. Louis
with the arch.
-
OK.
-
Did you go to the arch?
-
No?
-
You should go to the arch.
-
It looks like that.
-
It has a big base.
-
So it looks so beautiful.
-
It's thicker at the base.
-
This was based on a
mathematical equation.
-
The mathematical equation
it was based on was cosh x.
-
What is cosh as a function?
-
Now I'm testing you,
but I'm not judging you.
-
If you forgot--
-
STUDENT: e to the x.
-
DR. MAGDALENA TODA:
e to the x plus e
-
to the negative x over 3.
-
If it's minus, it's called sinh.
-
So the one with [? parts. ?]
You can have x/a,
-
and you can have 1/a in front.
-
It's still called a catenary.
-
Now what is-- this
is a catenary.
-
The shape of the arch of
St. Louis is a catenary.
-
But you are more used to the
catenary upside down, which
-
is any necklace.
-
Do you have a necklace?
-
If you take any
necklace-- that is,
-
it has to be homogeneous,
not one of those,
-
like you have a pearl hanging,
or you have several beads.
-
No.
-
It has to be a
homogeneous metal.
-
Think gold, solid gold, but
that kind of liquid gold.
-
Do you know what
I'm talking about?
-
Those beautiful bracelets
or necklaces that are fluid,
-
and you cannot even see
the different links.
-
So you hang it at
the same height.
-
What you get-- Galileo
proved it was not
-
a parabola because people at
that time were really stupid.
-
So they thought, hang a
chain from a woman's neck
-
or some sort of
beautiful jewelry,
-
it must be a parabola because
it looks like a parabola.
-
And Galileo Galilei says,
these guys are nuts.
-
They don't know any mathematics,
any physics, any astronomy.
-
So he proved in no time
that thing, the chain,
-
cannot be a parabola.
-
And he actually
came up with that.
-
If a is 1, you just
have the cosh x.
-
So this is the chain.
-
If you take the chain--
if you take the chain--
-
that's a chain upside down.
-
If you take a chain--
let's say y equals cosh
-
x to make it easier--
and revolve that chain,
-
you get a surface of revolution.
-
-
And this surface of
revolution is called catenoid.
-
-
How can you get the catenoid
as a minimal surface, expressed
-
as the minimum surface?
-
There are people
who can do that.
-
They have the
ability to do that.
-
And they tried to have
an experimental thing
-
at the Science Spectrum as well.
-
And they did a beautiful job.
-
I was there.
-
So they took two
circles made of plastic.
-
You can have them be
circles made of wood,
-
made of iron or
steel or anything.
-
But they have to be
equal, equal circles.
-
And you touch them,
and you dip them
-
both at the same time
into the soap solution.
-
And then you pull
it out very gently
-
because you have
to be very smart
-
and very-- be like a surgeon.
-
If your hands start shaking,
it's goodbye minimal surfaces
-
because they break.
-
They collapse.
-
So you have to pull those
circles with the same force,
-
gently, one away from the other.
-
What you're going
to get is going
-
to be a film that looks
exactly like that.
-
These are the circles.
-
After a certain distance
of moving them apart,
-
the soap film will
collapse and will burst.
-
There's no more surface inside.
-
But up to that moment,
you have a catenoid.
-
And this catenoid is
a minimal surface.
-
It's trying to-- of
the frame you gave it,
-
which is the wire frame--
minimize the area.
-
It's not going to be a cylinder.
-
It's way too much area.
-
It's going to be something
smaller than that,
-
so something that says,
I'm an elastic surface.
-
I'm occupying as
little area as I
-
can because I live in
a world of scarcity,
-
and I try to occupy
as little as I can.
-
So it's based on a
principle of physics.
-
The surface tension
of the soap films
-
will create this
minimization of the area.
-
So all you need to do is
remember you know the helicoid
-
and catenoid only because
you're honors students.
-
So thank [INAUDIBLE] college
for giving you this opportunity.
-
All right?
-
I'm not kidding.
-
It may sound like a joke, but
it's half joke, half truth.
-
We learn learn a little
bit more interesting stuff
-
than other kids.
-
Enjoy your week.
-
Good luck with homework.
-
Come bug me abut any kind
of homework [INAUDIBLE].
-
-
STUDENT: Do you
know if I can talk
-
to people about [INAUDIBLE]?
-
-
DR. MAGDALENA TODA:
Actually, my [INAUDIBLE].
-
She is the one who
does [INAUDIBLE].
-
But I can take you to her so
you can start [INAUDIBLE].
-
I think it would be a very
interesting [INAUDIBLE].
-
Maybe.
-
[INAUDIBLE]
-
-
STUDENT: OK.
-
DR. MAGDALENA TODA:
Second floor, [INAUDIBLE].
-
This is the [INAUDIBLE].
-
You have to go all
the way behind.
-
STUDENT: OK.
-
OK.
-
STUDENT: [INAUDIBLE]
-
-
DR. MAGDALENA TODA:
[INAUDIBLE] because I don't
-
want to give you anything new.
-
I don't want to get you
in any kind of trouble.
-
The problems that I solved
on the board are primarily,
-
I would say, 60% of what
you'll see on the midterm.
-
It's something that
we covered in class.
-
And the other 40% will be
something not too hard,
-
but something standard out of
your WeBWork homework, the one
-
that you studied.
-
It shouldn't be hard.
-
STUDENT: Thank you.
-
DR. MAGDALENA TODA:
You're welcome.
-
STUDENT: We're trying to
join the Honors Society.
-
But we can't make
that thing tomorrow.
-
Can we still join?
-
DR. MAGDALENA TODA:
You can still join.
-
Remind me to give you the
golden pin, the brochures, all
-
the information.
-
And then when you get those,
you'll give me the $35.
-
It's a lifetime thing.
-
STUDENT: Awesome.
-
Thank you.
-
DR. MAGDALENA TODA:
You're welcome.
-
Both of you want to--
-
STUDENT: Yeah.
-
DR. MAGDALENA TODA: And
you cannot come tomorrow?
-
STUDENT: Yeah.
-
I have my--
-
DR. MAGDALENA TODA: I wanted to
bring something, some snacks.
-
But I don't know.
-
I need to count and see
how many people can come.
-
And it's going to
be in my office.
-
STUDENT: OK.
-
DR. MAGDALENA TODA: All right.
-
STUDENT: Were you in
the tennis tournament?
-
STUDENT: Yeah.
-
STUDENT: You're the guy who won?
-
STUDENT: Yeah.
-
STUDENT: Congratulations.
-
I was like, I know that name.
-
He's in my [INAUDIBLE].
-
DR. MAGDALENA TODA: You won it?
-
STUDENT: Yeah.
-
DR. MAGDALENA TODA:
The tennis tournament?
-
STUDENT: Yeah.
-
It was [INAUDIBLE].
-
DR. MAGDALENA TODA:
Congratulations.
-
Why don't you blab a
little bit about yourself?
-
You're so modest.
-
You never say anything.
-
STUDENT: It's all right.
-
STUDENT: I'm sorry.
-
STUDENT: No.
-
STUDENT: It's not a big deal.
-
STUDENT: Were people good?
-
Yeah?
-
DR. MAGDALENA TODA: All right.
-
STUDENT: I have my extra credit.
-
